/*
 * dispatcher module
 *
 * Copyright (C) 2004-2006 FhG Fokus
 * Copyright (C) 2005 Voice-System.ro
 * Copyright (C) 2015 Daniel-Constantin Mierla (asipto.com)
 *
 * This file is part of Kamailio, a free SIP server.
 *
 * Kamailio is free software; you can redistribute it and/or modify
 * it under the terms of the GNU General Public License as published by
 * the Free Software Foundation; either version 2 of the License, or
 * (at your option) any later version
 *
 * Kamailio is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program; if not, write to the Free Software
 * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA  02110-1301  USA
 */

/*! \file
 * \ingroup dispatcher
 * \brief Dispatcher :: Dispatch
 */

#include <stdio.h>
#include <string.h>
#include <stdlib.h>
#include <stdint.h>
#include <time.h>
#include <math.h>

#include "../../core/ut.h"
#include "../../core/trim.h"
#include "../../core/dprint.h"
#include "../../core/action.h"
#include "../../core/route.h"
#include "../../core/dset.h"
#include "../../core/mem/shm_mem.h"
#include "../../core/parser/parse_uri.h"
#include "../../core/parser/parse_from.h"
#include "../../core/parser/parse_param.h"
#include "../../core/xavp.h"
#include "../../core/parser/digest/digest.h"
#include "../../core/resolve.h"
#include "../../core/lvalue.h"
#include "../../modules/tm/tm_load.h"
#include "../../lib/srdb1/db.h"
#include "../../lib/srdb1/db_res.h"
#include "../../core/str.h"
#include "../../core/script_cb.h"
#include "../../core/kemi.h"
#include "../../core/fmsg.h"

#include "ds_ht.h"
#include "api.h"
#include "dispatch.h"

#define DS_TABLE_VERSION 1
#define DS_TABLE_VERSION2 2
#define DS_TABLE_VERSION3 3
#define DS_TABLE_VERSION4 4

#define DS_ALG_HASHCALLID 0
#define DS_ALG_HASHFROMURI 1
#define DS_ALG_HASHTOURI 2
#define DS_ALG_HASHRURI 3
#define DS_ALG_ROUNDROBIN 4
#define DS_ALG_HASHAUTHUSER 5
#define DS_ALG_RANDOM 6
#define DS_ALG_HASHPV 7
#define DS_ALG_SERIAL 8
#define DS_ALG_WEIGHT 9
#define DS_ALG_CALLLOAD 10
#define DS_ALG_RELWEIGHT 11
#define DS_ALG_PARALLEL 12
#define DS_ALG_LATENCY 13
#define DS_ALG_OVERLOAD 64 /* 2^6 - can be also used as a flag */

#define DS_HN_SIZE 256

#define DS_MATCHED_ADDR 1
#define DS_MATCHED_PORT (1 << 1)
#define DS_MATCHED_PROTO (1 << 2)
#define DS_MATCHED_SOCK (1 << 3)

/* increment call load */
#define DS_LOAD_INC(dgrp, didx)      \
	do {                             \
		lock_get(&(dgrp)->lock);     \
		(dgrp)->dlist[didx].dload++; \
		lock_release(&(dgrp)->lock); \
	} while(0)

/* decrement call load */
#define DS_LOAD_DEC(dgrp, didx)                     \
	do {                                            \
		lock_get(&(dgrp)->lock);                    \
		if(likely((dgrp)->dlist[didx].dload > 0)) { \
			(dgrp)->dlist[didx].dload--;            \
		}                                           \
		lock_release(&(dgrp)->lock);                \
	} while(0)

static int _ds_table_version = DS_TABLE_VERSION;

static ds_ht_t *_dsht_load = NULL;

static int *_ds_ping_active = NULL;

extern int ds_force_dst;
extern str ds_event_callback;
extern int ds_ping_latency_stats;
extern int ds_retain_latency_stats;
extern float ds_latency_estimator_alpha;
extern int ds_attrs_none;
extern param_t *ds_db_extra_attrs_list;
extern int ds_load_mode;
extern uint32_t ds_dns_mode;
extern int ds_dns_ttl;

static db_func_t ds_dbf;
static db1_con_t *ds_db_handle = NULL;

static ds_set_t **ds_lists = NULL;

static int *ds_list_nr = NULL;
static int *ds_crt_idx = NULL;
static int *ds_next_idx = NULL;

static ds_set_t *ds_strictest_node = NULL;
static int ds_strictest_idx;
static int ds_strictness;

#define _ds_list (ds_lists[*ds_crt_idx])
#define _ds_list_nr (*ds_list_nr)

static void ds_run_route(
		struct sip_msg *msg, str *uri, char *route, ds_rctx_t *rctx);

void shuffle_uint100array(unsigned int *arr);
void shuffle_char100array(char *arr);
int ds_reinit_rweight_on_state_change(
		int old_state, int new_state, ds_set_t *dset);

/**
 *
 */
int ds_ping_active_init(void)
{
	if(_ds_ping_active != NULL)
		return 0;
	_ds_ping_active = (int *)shm_malloc(sizeof(int));
	if(_ds_ping_active == NULL) {
		SHM_MEM_ERROR;
		return -1;
	}
	*_ds_ping_active = 1;
	return 0;
}

/**
 *
 */
int ds_ping_active_get(void)
{
	if(_ds_ping_active == NULL)
		return -1;
	return *_ds_ping_active;
}

/**
 *
 */
int ds_ping_active_set(int v)
{
	if(_ds_ping_active == NULL)
		return -1;
	*_ds_ping_active = v;
	return 0;
}

/**
 *
 */
int ds_hash_load_init(unsigned int htsize, int expire, int initexpire)
{
	if(_dsht_load != NULL)
		return 0;
	_dsht_load = ds_ht_init(htsize, expire, initexpire);
	if(_dsht_load == NULL)
		return -1;
	return 0;
}

/**
 *
 */
int ds_hash_load_destroy(void)
{
	if(_dsht_load == NULL)
		return -1;
	ds_ht_destroy(_dsht_load);
	_dsht_load = NULL;
	return 0;
}

/**
 *
 */
static inline int ds_get_index(int group, int ds_list_idx, ds_set_t **index)
{
	ds_set_t *si = NULL;

	if(index == NULL || group < 0 || ds_lists[ds_list_idx] == NULL)
		return -1;

	/* get the index of the set */
	si = ds_avl_find(ds_lists[ds_list_idx], group);

	if(si == NULL)
		return -1;

	*index = si;
	return 0;
}

/**
 * Recursivly iterate over ds_set and execute callback
 */
void ds_iter_set(ds_set_t *node,
		void (*ds_action_cb)(ds_set_t *node, int i, void *arg),
		void *ds_action_arg)
{
	int i;

	if(!node)
		return;

	for(i = 0; i < 2; ++i)
		ds_iter_set(node->next[i], ds_action_cb, ds_action_arg);

	for(i = 0; i < node->nr; i++) {
		ds_action_cb(node, i, ds_action_arg);
	}

	return;
}

void ds_log_dst_cb(ds_set_t *node, int i, void *arg)
{
	LM_DBG("dst>> %d %.*s %d %d (%.*s,%d,%d,%d)\n", node->id,
			node->dlist[i].uri.len, node->dlist[i].uri.s, node->dlist[i].flags,
			node->dlist[i].priority, node->dlist[i].attrs.duid.len,
			node->dlist[i].attrs.duid.s, node->dlist[i].attrs.maxload,
			node->dlist[i].attrs.weight, node->dlist[i].attrs.rweight);
}

/**
 * Recursivly print ds_set
 */
void ds_log_set(ds_set_t *node)
{
	ds_iter_set(node, &ds_log_dst_cb, NULL);

	return;
}

/**
 *
 */
int ds_log_sets(void)
{
	if(_ds_list == NULL)
		return -1;

	ds_log_set(_ds_list);

	return 0;
}

/**
 *
 */
int ds_init_data(void)
{
	int *p;

	ds_lists = (ds_set_t **)shm_malloc(2 * sizeof(ds_set_t *));
	if(!ds_lists) {
		SHM_MEM_ERROR;
		return -1;
	}
	memset(ds_lists, 0, 2 * sizeof(ds_set_t *));


	p = (int *)shm_malloc(3 * sizeof(int));
	if(!p) {
		shm_free(ds_lists);
		SHM_MEM_ERROR;
		return -1;
	}
	memset(p, 0, 3 * sizeof(int));

	ds_crt_idx = p;
	ds_next_idx = p + 1;
	ds_list_nr = p + 2;
	*ds_crt_idx = *ds_next_idx = 0;

	return 0;
}

/**
 *
 */
int ds_set_attrs(ds_dest_t *dest, str *vattrs)
{
	param_t *params_list = NULL;
	param_hooks_t phooks;
	param_t *pit = NULL;
	str param;
	int tmp_ival = 0;
	str sattrs;

	if(vattrs == NULL || vattrs->len <= 0) {
		if(ds_attrs_none == 0) {
			return 0;
		}
		sattrs.s = "none=yes";
		sattrs.len = 8;
	} else {
		sattrs = *vattrs;
	}
	if(sattrs.s[sattrs.len - 1] == ';')
		sattrs.len--;
	/* clone in shm */
	dest->attrs.body.s = (char *)shm_malloc(sattrs.len + 1);
	if(dest->attrs.body.s == NULL) {
		SHM_MEM_ERROR;
		return -1;
	}
	memcpy(dest->attrs.body.s, sattrs.s, sattrs.len);
	dest->attrs.body.s[sattrs.len] = '\0';
	dest->attrs.body.len = sattrs.len;

	param = dest->attrs.body;
	if(parse_params(&param, CLASS_ANY, &phooks, &params_list) < 0)
		return -1;
	for(pit = params_list; pit; pit = pit->next) {
		if(pit->name.len == 4 && strncasecmp(pit->name.s, "duid", 4) == 0) {
			dest->attrs.duid = pit->body;
		} else if(pit->name.len == 2
				  && strncasecmp(pit->name.s, "cc", 2) == 0) {
			str2sint(&pit->body, &dest->attrs.congestion_control);
		} else if(pit->name.len == 6
				  && strncasecmp(pit->name.s, "weight", 6) == 0) {
			tmp_ival = 0;
			str2sint(&pit->body, &tmp_ival);
			if(tmp_ival >= 1 && tmp_ival <= 100) {
				dest->attrs.weight = tmp_ival;
			} else {
				dest->attrs.weight = 0;
				LM_ERR("weight %d not in 1-100 range - ignoring destination\n",
						tmp_ival);
			}
		} else if(pit->name.len == 7
				  && strncasecmp(pit->name.s, "latency", 7) == 0) {
			int initial_latency = 0;
			if(str2sint(&pit->body, &initial_latency) == 0)
				latency_stats_init(
						&dest->latency_stats, initial_latency, 10000);
		} else if(pit->name.len == 7
				  && strncasecmp(pit->name.s, "maxload", 7) == 0) {
			str2sint(&pit->body, &dest->attrs.maxload);
		} else if(pit->name.len == 6
				  && strncasecmp(pit->name.s, "socket", 6) == 0) {
			dest->attrs.socket = pit->body;
		} else if(pit->name.len == 8
				  && strncasecmp(pit->name.s, "sockname", 8) == 0) {
			dest->attrs.sockname = pit->body;
		} else if(pit->name.len == 7
				  && strncasecmp(pit->name.s, "rweight", 7) == 0) {
			tmp_ival = 0;
			str2sint(&pit->body, &tmp_ival);
			if(tmp_ival >= 1 && tmp_ival <= 100) {
				dest->attrs.rweight = tmp_ival;
			} else {
				dest->attrs.rweight = 0;
				LM_WARN("rweight %d not in 1-100 range - ignoring\n", tmp_ival);
			}
		} else if(pit->name.len == 9
				  && strncasecmp(pit->name.s, "ping_from", 9) == 0) {
			dest->attrs.ping_from = pit->body;
		} else if(pit->name.len == 7
				  && strncasecmp(pit->name.s, "obproxy", 7) == 0) {
			dest->attrs.obproxy = pit->body;
		} else if(pit->name.len == 5
				  && strncasecmp(pit->name.s, "ocmin", 5) == 0) {
			str2int(&pit->body, &dest->ocdata.ocmin);
		} else if(pit->name.len == 5
				  && strncasecmp(pit->name.s, "ocmax", 5) == 0) {
			str2int(&pit->body, &dest->ocdata.ocmax);
		} else if(pit->name.len == 6
				  && strncasecmp(pit->name.s, "ocrate", 6) == 0) {
			str2int(&pit->body, &dest->ocdata.ocrate);
		}
	}
	if(dest->ocdata.ocmax > 100) {
		dest->ocdata.ocmax = 100;
	}
	if(dest->ocdata.ocmax <= 0) {
		dest->ocdata.ocmax = 100;
	}
	if(dest->ocdata.ocmin > 100) {
		dest->ocdata.ocmin = 0;
	}
	if(dest->ocdata.ocmin < 0) {
		dest->ocdata.ocmin = 0;
	}
	if(dest->ocdata.ocrate > 100) {
		dest->ocdata.ocrate = 0;
	}
	if(dest->ocdata.ocrate < dest->ocdata.ocmin) {
		dest->ocdata.ocrate = dest->ocdata.ocmin;
	}
	if(dest->ocdata.ocrate > dest->ocdata.ocmax) {
		dest->ocdata.ocrate = dest->ocdata.ocmax;
	}

	if(params_list)
		free_params(params_list);
	return 0;
}

/**
 *
 */
void ds_oc_prepare(ds_dest_t *dp)
{
	int i;
	for(i = 0; i < dp->ocdata.ocrate; i++) {
		dp->ocdata.ocdist[i] = '0';
	}
	for(i = dp->ocdata.ocrate; i < 100; i++) {
		dp->ocdata.ocdist[i] = '1';
	}
	shuffle_char100array(dp->ocdata.ocdist);
}

/**
 *
 */
int ds_oc_set_attrs(
		sip_msg_t *msg, int setid, str *duri, int irval, int itval, int isval)
{
	int i = 0;
	int ret = -1;
	ds_set_t *idx = NULL;
	struct timeval tnow;
	struct timeval tdiff;

	if(_ds_list == NULL || _ds_list_nr <= 0) {
		LM_ERR("the list is null\n");
		return -1;
	}

	/* get the index of the set */
	if(ds_get_index(setid, *ds_crt_idx, &idx) != 0) {
		LM_ERR("destination set [%d] not found\n", setid);
		return -1;
	}
	LM_DBG("updating oc attrs for %d %.*s to rate %d validity %d seq %d\n",
			setid, duri->len, duri->s, irval, itval, isval);

	gettimeofday(&tnow, NULL);
	timerclear(&tdiff);

	/* interval set to itval or to default 500 milliseconds */
	tdiff.tv_sec = (((itval > 0) ? itval : 500) * 1000) / 1000000;
	tdiff.tv_usec = (((itval > 0) ? itval : 500) * 1000) % 1000000;

	for(i = 0; i < idx->nr; i++) {
		if(idx->dlist[i].uri.len == duri->len
				&& strncasecmp(idx->dlist[i].uri.s, duri->s, duri->len) == 0) {
			if(idx->dlist[i].ocdata.ocseq >= isval) {
				LM_DBG("skipping entry %d due to seq condition\n", i);
				continue;
			}
			idx->dlist[i].ocdata.ocrate = irval;
			if(idx->dlist[i].ocdata.ocrate < idx->dlist[i].ocdata.ocmin) {
				idx->dlist[i].ocdata.ocrate = idx->dlist[i].ocdata.ocmin;
			}
			if(idx->dlist[i].ocdata.ocrate > idx->dlist[i].ocdata.ocmax) {
				idx->dlist[i].ocdata.ocrate = idx->dlist[i].ocdata.ocmax;
			}
			ds_oc_prepare(&idx->dlist[i]);
			timeradd(&tnow, &tdiff, &idx->dlist[i].ocdata.octime);
			idx->dlist[i].ocdata.ocseq = isval;
			ret = 1;
			LM_DBG("updated entry %d\n", i);
		}
	}
	return ret;
}

/**
 *
 */
static inline int ds_oc_skip(ds_set_t *dsg, int alg, int n)
{
	int ret;
	struct timeval tnow;

	if(alg != DS_ALG_OVERLOAD) {
		return 0;
	}

	gettimeofday(&tnow, NULL);

	if(timercmp(&dsg->dlist[n].ocdata.octime, &tnow, <)) {
		/* over the time interval validity - use it */
		LM_DBG("time validity not matching\n");
		return 0;
	}
	if(dsg->dlist[n].ocdata.ocdist[dsg->dlist[n].ocdata.ocidx] == '1') {
		/* use it */
		ret = 0;
	} else {
		/* skip it */
		ret = 1;
	}
	dsg->dlist[n].ocdata.ocidx = (dsg->dlist[n].ocdata.ocidx + 1) % 100;

	return ret;
}

/**
 *
 */
ds_dest_t *pack_dest(str iuri, int flags, int priority, str *attrs, int dload)
{
	ds_dest_t *dp = NULL;
	/* For DNS-Lookups */
	char hn[DS_HN_SIZE];
	char ub[512];
	struct hostent *he;
	struct sip_uri puri;
	str host;
	int port, proto;
	char c = 0;
	str uri;
	unsigned short sport = 0;
	char sproto = PROTO_NONE;

	uri = iuri;
	/* check uri */
	if(parse_uri(uri.s, uri.len, &puri) != 0) {
		if(iuri.len > 4 && strncmp(iuri.s, "sip:", 4) != 0 && iuri.len < 500) {
			memcpy(ub, "sip:", 4);
			memcpy(ub + 4, iuri.s, iuri.len);
			ub[iuri.len + 4] = '\0';
			uri.s = ub;
			uri.len = iuri.len + 4;
			if(parse_uri(uri.s, uri.len, &puri) != 0) {
				LM_ERR("bad uri [%.*s]\n", iuri.len, iuri.s);
				goto err;
			} else {
				LM_INFO("uri without sip scheme - fixing it: %.*s\n", iuri.len,
						iuri.s);
			}
		} else {
			LM_ERR("bad uri [%.*s]\n", iuri.len, iuri.s);
			goto err;
		}
	}

	if(puri.host.len > (DS_HN_SIZE - 2)) {
		LM_ERR("hostname in uri is too long [%.*s]\n", uri.len, uri.s);
		goto err;
	}

	/* skip IPv6 references if IPv6 lookups are disabled */
	if(default_core_cfg.dns_try_ipv6 == 0 && puri.host.s[0] == '['
			&& puri.host.s[puri.host.len - 1] == ']') {
		LM_DBG("skipping IPv6 record %.*s\n", puri.host.len, puri.host.s);
		return NULL;
	}

	/* store uri */
	dp = (ds_dest_t *)shm_malloc(sizeof(ds_dest_t));
	if(dp == NULL) {
		SHM_MEM_ERROR;
		goto err;
	}
	memset(dp, 0, sizeof(ds_dest_t));

	dp->uri.s = (char *)shm_malloc((uri.len + 1) * sizeof(char));
	if(dp->uri.s == NULL) {
		SHM_MEM_ERROR;
		goto err;
	}
	strncpy(dp->uri.s, uri.s, uri.len);
	dp->uri.s[uri.len] = '\0';
	dp->uri.len = uri.len;

	dp->flags = flags;
	dp->priority = priority;
	dp->dload = dload;
	dp->ocdata.ocmax = 100;

	if(ds_set_attrs(dp, attrs) < 0) {
		LM_ERR("cannot set attributes!\n");
		goto err;
	}

	/* set send socket by name or address */
	if(dp->attrs.sockname.s && dp->attrs.sockname.len > 0) {
		dp->sock = ksr_get_socket_by_name(&dp->attrs.sockname);
		if(dp->sock == 0) {
			LM_ERR("non-local socket name <%.*s>\n", dp->attrs.sockname.len,
					dp->attrs.sockname.s);
			goto err;
		}
	} else if(dp->attrs.socket.s && dp->attrs.socket.len > 0) {
		/* parse_phostport(...) expects 0-terminated string
		 * - after socket parameter is either ';' or '\0' */
		STR_VTOZ(dp->attrs.socket.s[dp->attrs.socket.len], c);
		if(parse_phostport(
				   dp->attrs.socket.s, &host.s, &host.len, &port, &proto)
				!= 0) {
			LM_ERR("bad socket <%.*s>\n", dp->attrs.socket.len,
					dp->attrs.socket.s);
			STR_ZTOV(dp->attrs.socket.s[dp->attrs.socket.len], c);
			goto err;
		}
		STR_ZTOV(dp->attrs.socket.s[dp->attrs.socket.len], c);
		dp->sock = grep_sock_info(&host, (unsigned short)port, proto);
		if(dp->sock == 0) {
			LM_ERR("non-local socket <%.*s>\n", dp->attrs.socket.len,
					dp->attrs.socket.s);
			goto err;
		}
	} else if(ds_default_sockinfo) {
		dp->sock = ds_default_sockinfo;
	}


	dp->host.s = dp->uri.s + (puri.host.s - uri.s);
	dp->host.len = puri.host.len;

	/* Copy the port out of the URI */
	dp->port = puri.port_no;
	/* Copy the proto out of the URI */
	dp->proto = puri.proto;

	/* Do a DNS-Lookup for the Host-Name, if not disabled via dst flags */
	if(dp->flags & DS_NODNSARES_DST) {
		dp->irmode |= DS_IRMODE_NOIPADDR;
	} else if(ds_dns_mode & (DS_DNS_MODE_INIT | DS_DNS_MODE_TIMER)) {
		dns_set_local_ttl(ds_dns_ttl);
		if(ds_dns_mode & DS_DNS_MODE_QSRV) {
			sport = dp->port;
			sproto = (char)dp->proto;
			he = sip_resolvehost(&dp->host, &sport, &sproto);
			if(he != 0) {
				if(sport != 0) {
					dp->port = sport;
				}
				if(sproto != PROTO_NONE) {
					dp->proto = sproto;
				}
			}
		} else {
			/* The Hostname needs to be \0 terminated for resolvehost, so we
			 * make a copy here. */
			strncpy(hn, puri.host.s, puri.host.len);
			hn[puri.host.len] = '\0';
			he = resolvehost(hn);
		}
		dns_set_local_ttl(0);
		if(he == 0) {
			LM_ERR("could not resolve %.*s (missing no-probing flag?!?)\n",
					puri.host.len, puri.host.s);
			goto err;
		} else {
			/* Store hostent in the dispatcher structure */
			hostent2ip_addr(&dp->ip_address, he, 0);
		}
	}

	ds_oc_prepare(dp);

	return dp;
err:
	if(dp != NULL) {
		if(dp->uri.s != NULL)
			shm_free(dp->uri.s);
		if(dp->attrs.body.s != NULL)
			shm_free(dp->attrs.body.s);
		shm_free(dp);
	}

	return NULL;
}

/**
 *
 */
int add_dest2list(int id, str uri, int flags, int priority, str *attrs,
		int list_idx, int *setn, int dload, ds_latency_stats_t *latency_stats)
{
	ds_dest_t *dp = NULL;
	ds_set_t *sp = NULL;
	ds_dest_t *dp0 = NULL;
	ds_dest_t *dp1 = NULL;

	dp = pack_dest(uri, flags, priority, attrs, dload);
	if(!dp)
		goto err;

	if(latency_stats != NULL) {
		dp->latency_stats.stdev = latency_stats->stdev;
		dp->latency_stats.m2 = latency_stats->m2;
		dp->latency_stats.max = latency_stats->max;
		dp->latency_stats.min = latency_stats->min;
		dp->latency_stats.average = latency_stats->average;
		dp->latency_stats.estimate = latency_stats->estimate;
		dp->latency_stats.count = latency_stats->count;
		dp->latency_stats.timeout = latency_stats->timeout;
	}

	sp = ds_avl_insert(&ds_lists[list_idx], id, setn);
	if(!sp) {
		LM_ERR("no more memory.\n");
		goto err;
	}
	sp->nr++;

	if(sp->dlist == NULL) {
		sp->dlist = dp;
	} else {
		dp1 = NULL;
		dp0 = sp->dlist;
		/* highest priority last -> reindex will copy backwards */
		while(dp0) {
			if(dp0->priority > dp->priority)
				break;
			dp1 = dp0;
			dp0 = dp0->next;
		}
		if(dp1 == NULL) {
			dp->next = sp->dlist;
			sp->dlist = dp;
		} else {
			dp->next = dp1->next;
			dp1->next = dp;
		}
	}

	LM_DBG("dest [%d/%d] <%.*s>\n", sp->id, sp->nr, dp->uri.len, dp->uri.s);

	return 0;
err:
	if(dp != NULL) {
		if(dp->uri.s != NULL)
			shm_free(dp->uri.s);
		if(dp->attrs.body.s != NULL)
			shm_free(dp->attrs.body.s);
		shm_free(dp);
	}

	return -1;
}


/* for internal usage; arr must be arr[100] */
void shuffle_uint100array(unsigned int *arr)
{
	int k;
	int j;
	unsigned int t;
	if(arr == NULL)
		return;
	for(j = 0; j < 100; j++) {
		k = j + (kam_rand() % (100 - j));
		t = arr[j];
		arr[j] = arr[k];
		arr[k] = t;
	}
}


/* for internal usage; arr must be arr[100] */
void shuffle_char100array(char *arr)
{
	int k;
	int j;
	char t;
	if(arr == NULL)
		return;
	for(j = 0; j < 100; j++) {
		k = j + (kam_rand() % (100 - j));
		t = arr[j];
		arr[j] = arr[k];
		arr[k] = t;
	}
}


/**
 * Initialize the relative weight distribution for a destination set
 * - fill the array of 0..99 elements where to keep the index of the
 *   destination address to be used. The Nth call will use
 *   the address with the index at possition N%100
 */
int dp_init_relative_weights(ds_set_t *dset)
{
	int j;
	int k;
	int t;
	int *ds_dests_flags = NULL;
	int *ds_dests_rweights = NULL;
	int current_slice;
	int rw_sum;
	unsigned int last_insert;

	if(dset == NULL || dset->dlist == NULL || dset->nr < 2)
		return -1;

	/* local copy to avoid synchronization problems */
	ds_dests_flags = pkg_malloc(sizeof(int) * dset->nr);
	if(ds_dests_flags == NULL) {
		PKG_MEM_ERROR;
		return -1;
	}
	ds_dests_rweights = pkg_malloc(sizeof(int) * dset->nr);
	if(ds_dests_rweights == NULL) {
		PKG_MEM_ERROR;
		pkg_free(ds_dests_flags);
		return -1;
	}


	/* needed to sync the rwlist access */
	lock_get(&dset->lock);
	rw_sum = 0;
	/* find the sum of relative weights */
	for(j = 0; j < dset->nr; j++) {
		ds_dests_flags[j] = dset->dlist[j].flags;
		ds_dests_rweights[j] = dset->dlist[j].attrs.rweight;
		if(ds_skip_dst(ds_dests_flags[j]))
			continue;
		rw_sum += ds_dests_rweights[j];
	}

	if(rw_sum == 0)
		goto ret;

	/* fill the array based on the relative weight of each destination */
	t = 0;
	for(j = 0; j < dset->nr; j++) {
		if(ds_skip_dst(ds_dests_flags[j]))
			continue;

		current_slice = ds_dests_rweights[j] * 100 / rw_sum; /* truncate here */
		LM_DBG("rw_sum[%d][%d][%d]\n", j, rw_sum, current_slice);
		for(k = 0; k < current_slice; k++) {
			dset->rwlist[t] = (unsigned int)j;
			t++;
		}
	}

	/* if the array was not completely filled (i.e., the sum of rweights is
	 * less than 100 due to truncated), then use last address to fill the rest */
	last_insert = t > 0 ? dset->rwlist[t - 1] : (unsigned int)(dset->nr - 1);
	if(t < 100) {
		LM_INFO("extra rweight %d for last active destination in group %d\n",
				(100 - t), dset->id);
	}
	for(j = t; j < 100; j++)
		dset->rwlist[j] = last_insert;

	/* shuffle the content of the array in order to mix the selection
	 * of the addresses (e.g., if first address has weight=20, avoid
	 * sending first 20 calls to it, but ensure that within a 100 calls,
	 * 20 go to first address */
	shuffle_uint100array(dset->rwlist);
	goto ret;

ret:
	lock_release(&dset->lock);
	pkg_free(ds_dests_flags);
	pkg_free(ds_dests_rweights);
	return 0;
}


/**
 * Initialize the weight distribution for a destination set
 * - fill the array of 0..99 elements where to keep the index of the
 *   destination address to be used. The Nth call will use
 *   the address with the index at possition N%100
 */
int dp_init_weights(ds_set_t *dset)
{
	int j;
	int k;
	int t;

	if(dset == NULL || dset->dlist == NULL)
		return -1;

	/* is weight set for dst list? (first address must have weight!=0) */
	if(dset->dlist[0].attrs.weight == 0)
		return 0;

	/* first fill the array based on the weight of each destination
	 * - the weight is the percentage (e.g., if weight=20, the afferent
	 *   address gets its index 20 times in the array)
	 * - if the sum of weights is more than 100, the addresses over the
	 *   limit are ignored */
	t = 0;
	for(j = 0; j < dset->nr; j++) {
		for(k = 0; k < dset->dlist[j].attrs.weight; k++) {
			if(t >= 100)
				goto randomize;
			dset->wlist[t] = (unsigned int)j;
			t++;
		}
	}
	/* if the array was not completely filled (i.e., the sum of weights is
	 * less than 100), then use last address to fill the rest */
	if(t < 100) {
		LM_INFO("extra weight %d for last destination in group %d\n", (100 - t),
				dset->id);
	}
	for(; t < 100; t++)
		dset->wlist[t] = (unsigned int)(dset->nr - 1);
randomize:
	/* shuffle the content of the array in order to mix the selection
	 * of the addresses (e.g., if first address has weight=20, avoid
	 * sending first 20 calls to it, but ensure that within a 100 calls,
	 * 20 go to first address */
	shuffle_uint100array(dset->wlist);

	return 0;
}

/*! \brief  compact destinations from sets for fast access */
int reindex_dests(ds_set_t *node)
{
	int i = 0;
	int j = 0;

	if(!node)
		return 0;

	for(; i < 2; ++i) {
		int rc = reindex_dests(node->next[i]);
		if(rc != 0)
			return rc;
	}

	ds_dest_t *dp = NULL, *dp0 = NULL;

	dp0 = (ds_dest_t *)shm_malloc(node->nr * sizeof(ds_dest_t));
	if(dp0 == NULL) {
		SHM_MEM_ERROR;
		goto err1;
	}
	memset(dp0, 0, node->nr * sizeof(ds_dest_t));

	/* copy from the old pointer to destination, and then free it */
	for(j = node->nr - 1; j >= 0 && node->dlist != NULL; j--) {
		memcpy(&dp0[j], node->dlist, sizeof(ds_dest_t));
		if(j == node->nr - 1)
			dp0[j].next = NULL;
		else
			dp0[j].next = &dp0[j + 1];


		dp = node->dlist;
		node->dlist = dp->next;

		shm_free(dp);
		dp = NULL;
	}
	node->dlist = dp0;
	dp_init_weights(node);
	dp_init_relative_weights(node);

	return 0;

err1:
	return -1;
}

/*! \brief load groups of destinations from file */
int ds_load_list(char *lfile)
{
	char line[1024], *p;
	FILE *f = NULL;
	int id, setn, flags, priority;
	str uri;
	str attrs;
	ds_latency_stats_t *latency_stats;

	if((*ds_crt_idx) != (*ds_next_idx)) {
		LM_WARN("load command already generated, aborting reload...\n");
		return 0;
	}

	if(lfile == NULL || strlen(lfile) <= 0) {
		LM_ERR("bad list file\n");
		return -1;
	}

	f = fopen(lfile, "r");
	if(f == NULL) {
		LM_ERR("can't open list file [%s]\n", lfile);
		return -1;
	}

	id = setn = flags = priority = 0;

	*ds_next_idx = (*ds_crt_idx + 1) % 2;
	ds_avl_destroy(&ds_lists[*ds_next_idx]);

	p = fgets(line, 1024, f);
	while(p) {
		/* eat all white spaces */
		while(*p && (*p == ' ' || *p == '\t' || *p == '\r' || *p == '\n'))
			p++;
		if(*p == '\0' || *p == '#')
			goto next_line;

		/* get set id */
		id = 0;
		while(*p >= '0' && *p <= '9') {
			id = id * 10 + (*p - '0');
			p++;
		}

		/* eat all white spaces */
		while(*p && (*p == ' ' || *p == '\t' || *p == '\r' || *p == '\n'))
			p++;
		if(*p == '\0' || *p == '#') {
			LM_ERR("bad line [%s]\n", line);
			goto error;
		}

		/* get uri */
		uri.s = p;
		while(*p && *p != ' ' && *p != '\t' && *p != '\r' && *p != '\n'
				&& *p != '#')
			p++;
		uri.len = p - uri.s;

		/* eat all white spaces */
		while(*p && (*p == ' ' || *p == '\t' || *p == '\r' || *p == '\n'))
			p++;

		/* get flags */
		flags = 0;
		priority = 0;
		attrs.s = 0;
		attrs.len = 0;
		if(*p == '\0' || *p == '#')
			goto add_destination; /* no flags given */

		while(*p >= '0' && *p <= '9') {
			flags = flags * 10 + (*p - '0');
			p++;
		}

		/* eat all white spaces */
		while(*p && (*p == ' ' || *p == '\t' || *p == '\r' || *p == '\n'))
			p++;

		/* get priority */
		if(*p == '\0' || *p == '#')
			goto add_destination; /* no priority given */

		while(*p >= '0' && *p <= '9') {
			priority = priority * 10 + (*p - '0');
			p++;
		}

		/* eat all white spaces */
		while(*p && (*p == ' ' || *p == '\t' || *p == '\r' || *p == '\n'))
			p++;
		if(*p == '\0' || *p == '#')
			goto add_destination; /* no attrs given */

		/* get attributes */
		attrs.s = p;
		while(*p && *p != ' ' && *p != '\t' && *p != '\r' && *p != '\n')
			p++;
		attrs.len = p - attrs.s;

	add_destination:
		latency_stats = NULL;
		if(ds_ping_latency_stats && ds_retain_latency_stats) {
			latency_stats = latency_stats_find(id, &uri);
		}
		if(add_dest2list(id, uri, flags, priority, &attrs, *ds_next_idx, &setn,
				   0, latency_stats)
				!= 0) {
			LM_WARN("unable to add destination %.*s to set %d -- skipping\n",
					uri.len, uri.s, id);
			if(ds_load_mode == 1) {
				goto error;
			}
		}
	next_line:
		p = fgets(line, 1024, f);
	}

	if(reindex_dests(ds_lists[*ds_next_idx]) != 0) {
		LM_ERR("error on reindex\n");
		goto error;
	}

	fclose(f);
	f = NULL;
	/* Update list - should it be sync'ed? */
	_ds_list_nr = setn;
	*ds_crt_idx = *ds_next_idx;

	LM_DBG("found [%d] dest sets\n", _ds_list_nr);

	ds_log_sets();
	return 0;

error:
	if(f != NULL)
		fclose(f);
	ds_avl_destroy(&ds_lists[*ds_next_idx]);
	*ds_next_idx = *ds_crt_idx;
	return -1;
}

/**
 *
 */
int ds_connect_db(void)
{
	if(ds_db_url.s == NULL)
		return -1;

	if((ds_db_handle = ds_dbf.init(&ds_db_url)) == 0) {
		LM_ERR("cannot initialize db connection\n");
		return -1;
	}
	return 0;
}

/**
 *
 */
void ds_disconnect_db(void)
{
	if(ds_db_handle) {
		ds_dbf.close(ds_db_handle);
		ds_db_handle = 0;
	}
}

/*! \brief Initialize and verify DB stuff*/
int ds_init_db(void)
{
	int ret;

	if(ds_table_name.s == 0) {
		LM_ERR("invalid database name\n");
		return -1;
	}

	/* Find a database module */
	if(db_bind_mod(&ds_db_url, &ds_dbf) < 0) {
		LM_ERR("Unable to bind to a database driver\n");
		return -1;
	}

	if(ds_connect_db() != 0) {
		LM_ERR("unable to connect to the database\n");
		return -1;
	}

	_ds_table_version = db_table_version(&ds_dbf, ds_db_handle, &ds_table_name);
	if(_ds_table_version < 0) {
		LM_ERR("failed to query table version\n");
		return -1;
	} else if(_ds_table_version != DS_TABLE_VERSION
			  && _ds_table_version != DS_TABLE_VERSION2
			  && _ds_table_version != DS_TABLE_VERSION3
			  && _ds_table_version != DS_TABLE_VERSION4) {
		LM_ERR("invalid table version (found %d , required %d, %d, %d or %d)\n"
			   "(use kamdbctl reinit)\n",
				_ds_table_version, DS_TABLE_VERSION, DS_TABLE_VERSION2,
				DS_TABLE_VERSION3, DS_TABLE_VERSION4);
		return -1;
	}

	ret = ds_load_db();
	if(ret == -2) {
		LM_WARN("failure while loading one or more dispatcher entries\n");
		ret = 0;
	}

	ds_disconnect_db();

	return ret;
}

/*! \brief reload groups of destinations from DB*/
int ds_reload_db(void)
{
	int ret;

	if(ds_connect_db() != 0) {
		LM_ERR("unable to connect to the database\n");
		return -1;
	}
	ret = ds_load_db();
	if(ret == -2) {
		LM_WARN("failure while loading one or more dispatcher entries\n");
	}
	ds_disconnect_db();

	return ret;
}

/*! \brief load groups of destinations from DB*/
int ds_load_db(void)
{
	int i, id, nr_rows, setn;
	int flags;
	int priority;
	int nrcols;
	int dest_errs = 0;
	str uri;
	str attrs = {0, 0};
	db1_res_t *res;
	db_val_t *values;
	db_row_t *rows;
#define DS_DB_MAX_COLS 32
	db_key_t query_cols[DS_DB_MAX_COLS];
	param_t *pit = NULL;
	int nc;
	int plen;
#define DS_ATTRS_MAXSIZE 1024
	char ds_attrs_buf[DS_ATTRS_MAXSIZE];
	ds_latency_stats_t *latency_stats;

	query_cols[0] = &ds_set_id_col;
	query_cols[1] = &ds_dest_uri_col;
	query_cols[2] = &ds_dest_flags_col;
	query_cols[3] = &ds_dest_priority_col;
	query_cols[4] = &ds_dest_attrs_col;

	nrcols = 2;
	if(_ds_table_version == DS_TABLE_VERSION2) {
		nrcols = 3;
	} else if(_ds_table_version == DS_TABLE_VERSION3) {
		nrcols = 4;
	} else if(_ds_table_version == DS_TABLE_VERSION4) {
		nrcols = 5;
		for(pit = ds_db_extra_attrs_list; pit != NULL; pit = pit->next) {
			if(nrcols >= DS_DB_MAX_COLS) {
				LM_ERR("too many db columns: %d\n", nrcols);
				return -1;
			}
			query_cols[nrcols++] = &pit->body;
		}
	}

	if((*ds_crt_idx) != (*ds_next_idx)) {
		LM_WARN("load command already generated, aborting reload...\n");
		return 0;
	}

	if(ds_db_handle == NULL) {
		LM_ERR("invalid DB handler\n");
		return -1;
	}

	if(ds_dbf.use_table(ds_db_handle, &ds_table_name) < 0) {
		LM_ERR("error in use_table\n");
		return -1;
	}

	LM_DBG("loading dispatcher db records - nrcols: %d\n", nrcols);

	/*select the whole table and all the columns*/
	if(ds_dbf.query(ds_db_handle, 0, 0, 0, query_cols, 0, nrcols, 0, &res)
			< 0) {
		LM_ERR("error while querying database\n");
		return -1;
	}

	nr_rows = RES_ROW_N(res);
	rows = RES_ROWS(res);
	if(nr_rows == 0) {
		LM_WARN("no dispatching data in the db -- empty destination set\n");
	}

	setn = 0;
	*ds_next_idx = (*ds_crt_idx + 1) % 2;
	ds_avl_destroy(&ds_lists[*ds_next_idx]);

	for(i = 0; i < nr_rows; i++) {
		values = ROW_VALUES(rows + i);

		id = VAL_INT(values);
		uri.s = VAL_STR(values + 1).s;
		uri.len = strlen(uri.s);
		flags = 0;
		if(nrcols >= 3)
			flags = VAL_INT(values + 2);
		priority = 0;
		if(nrcols >= 4)
			priority = VAL_INT(values + 3);

		attrs.s = 0;
		attrs.len = 0;
		if(nrcols >= 5) {
			if(!VAL_NULL(values + 4)) {
				attrs.s = VAL_STR(values + 4).s;
				if(attrs.s)
					attrs.len = strlen(attrs.s);
			}
			if(ds_db_extra_attrs_list != NULL && nrcols > 5) {
				if(attrs.len > 0) {
					memcpy(ds_attrs_buf, attrs.s, attrs.len);
					if(ds_attrs_buf[attrs.len - 1] != ';') {
						ds_attrs_buf[attrs.len++] = ';';
					}
				}
				attrs.s = ds_attrs_buf;
				pit = ds_db_extra_attrs_list;
				for(nc = 5; nc < nrcols && pit != NULL; nc++) {
					if(!VAL_NULL(values + nc)
							&& strlen(VAL_STRING(values + nc)) > 0) {
						plen = snprintf(attrs.s + attrs.len,
								DS_ATTRS_MAXSIZE - attrs.len - 1, "%.*s=%s;",
								pit->name.len, pit->name.s,
								VAL_STRING(values + nc));
						if(plen <= 0
								|| plen >= DS_ATTRS_MAXSIZE - attrs.len - 1) {
							LM_ERR("cannot build attrs buffer\n");
							goto err2;
						}
						attrs.len += plen;
					}
					pit = pit->next;
				}
			}
		}
		LM_DBG("attributes string: [%.*s]\n", attrs.len,
				(attrs.s) ? attrs.s : "");
		latency_stats = NULL;
		if(ds_ping_latency_stats && ds_retain_latency_stats) {
			latency_stats = latency_stats_find(id, &uri);
		}
		if(add_dest2list(id, uri, flags, priority, &attrs, *ds_next_idx, &setn,
				   0, latency_stats)
				!= 0) {
			dest_errs++;
			LM_WARN("unable to add destination %.*s to set %d -- skipping\n",
					uri.len, uri.s, id);
			if(ds_load_mode == 1) {
				goto err2;
			}
		}
	}
	if(reindex_dests(ds_lists[*ds_next_idx]) != 0) {
		LM_ERR("error on reindex\n");
		goto err2;
	}

	ds_dbf.free_result(ds_db_handle, res);

	/* update data - should it be sync'ed? */
	_ds_list_nr = setn;
	*ds_crt_idx = *ds_next_idx;

	LM_DBG("found [%d] dest sets\n", _ds_list_nr);

	ds_log_sets();

	if(dest_errs > 0)
		return -2;
	return 0;

err2:
	ds_avl_destroy(&ds_lists[*ds_next_idx]);
	ds_dbf.free_result(ds_db_handle, res);
	*ds_next_idx = *ds_crt_idx;

	return -1;
}

/*! \brief called from dispatcher.c: free all*/
int ds_destroy_list(void)
{
	if(ds_lists) {
		ds_avl_destroy(&ds_lists[0]);
		ds_avl_destroy(&ds_lists[1]);
		shm_free(ds_lists);
	}

	if(ds_crt_idx)
		shm_free(ds_crt_idx);

	return 0;
}

/**
 *
 */
unsigned int ds_get_hash(str *x, str *y)
{
	char *p;
	register unsigned v;
	register unsigned h;

	if(!x && !y)
		return 0;
	h = 0;
	if(x && x->s) {
		p = x->s;
		if(x->len >= 4) {
			for(; p <= (x->s + x->len - 4); p += 4) {
				v = (*p << 24) + (p[1] << 16) + (p[2] << 8) + p[3];
				h += v ^ (v >> 3);
			}
		}
		v = 0;
		for(; p < (x->s + x->len); p++) {
			v <<= 8;
			v += *p;
		}
		h += v ^ (v >> 3);
	}
	if(y && y->s) {
		p = y->s;
		if(y->len >= 4) {
			for(; p <= (y->s + y->len - 4); p += 4) {
				v = (*p << 24) + (p[1] << 16) + (p[2] << 8) + p[3];
				h += v ^ (v >> 3);
			}
		}

		v = 0;
		for(; p < (y->s + y->len); p++) {
			v <<= 8;
			v += *p;
		}
		h += v ^ (v >> 3);
	}
	h = ((h) + (h >> 11)) + ((h >> 13) + (h >> 23));

	return (h) ? h : 1;
}


/*! \brief
 * gets the part of the uri we will use as a key for hashing
 * \param  key1       - will be filled with first part of the key
 *                       (uri user or "" if no user)
 * \param  key2       - will be filled with the second part of the key
 *                       (uri host:port)
 * \param  uri        - str with the whole uri
 * \param  parsed_uri - struct sip_uri pointer with the parsed uri
 *                       (it must point inside uri). It can be null
 *                       (in this case the uri will be parsed internally).
 * \param  flags  -    if & DS_HASH_USER_ONLY, only the user part of the uri
 *                      will be used
 * \return: -1 on error, 0 on success
 */
static inline int get_uri_hash_keys(
		str *key1, str *key2, str *uri, struct sip_uri *parsed_uri, int flags)
{
	struct sip_uri tmp_p_uri; /* used only if parsed_uri==0 */

	if(parsed_uri == 0) {
		if(parse_uri(uri->s, uri->len, &tmp_p_uri) < 0) {
			LM_ERR("invalid uri %.*s\n", uri->len, uri->len ? uri->s : "");
			goto error;
		}
		parsed_uri = &tmp_p_uri;
	}
	/* uri sanity checks */
	if(parsed_uri->host.s == 0) {
		LM_ERR("invalid uri, no host present: %.*s\n", uri->len,
				uri->len ? uri->s : "");
		goto error;
	}

	/* we want: user@host:port if port !=5060
	 *          user@host if port==5060
	 *          user if the user flag is set*/
	*key1 = parsed_uri->user;
	key2->s = 0;
	key2->len = 0;
	if(!(flags & DS_HASH_USER_ONLY)) { /* key2=host */
		*key2 = parsed_uri->host;
		/* add port if needed */
		if(parsed_uri->port.s != 0) { /* uri has a port */
			/* skip port if == 5060 or sips and == 5061 */
			if(parsed_uri->port_no
					!= ((parsed_uri->type == SIPS_URI_T) ? SIPS_PORT
														 : SIP_PORT))
				key2->len += parsed_uri->port.len + 1 /* ':' */;
		}
	}
	if(key1->s == 0) {
		LM_WARN("empty username in: %.*s\n", uri->len, uri->len ? uri->s : "");
	}
	return 0;
error:
	return -1;
}


/**
 *
 */
int ds_hash_fromuri(struct sip_msg *msg, unsigned int *hash)
{
	str from;
	str key1;
	str key2;

	if(msg == NULL || hash == NULL) {
		LM_ERR("bad parameters\n");
		return -1;
	}

	if(parse_from_header(msg) < 0) {
		LM_ERR("cannot parse From hdr\n");
		return -1;
	}

	if(msg->from == NULL || get_from(msg) == NULL) {
		LM_ERR("cannot get From uri\n");
		return -1;
	}

	from = get_from(msg)->uri;
	trim(&from);
	if(get_uri_hash_keys(&key1, &key2, &from, 0, ds_flags) < 0)
		return -1;
	*hash = ds_get_hash(&key1, &key2);

	return 0;
}


/**
 *
 */
int ds_hash_touri(struct sip_msg *msg, unsigned int *hash)
{
	str to;
	str key1;
	str key2;

	if(msg == NULL || hash == NULL) {
		LM_ERR("bad parameters\n");
		return -1;
	}
	if((msg->to == 0)
			&& ((parse_headers(msg, HDR_TO_F, 0) == -1) || (msg->to == 0))) {
		LM_ERR("cannot parse To hdr\n");
		return -1;
	}


	to = get_to(msg)->uri;
	trim(&to);

	if(get_uri_hash_keys(&key1, &key2, &to, 0, ds_flags) < 0)
		return -1;
	*hash = ds_get_hash(&key1, &key2);

	return 0;
}


/**
 *
 */
int ds_hash_callid(struct sip_msg *msg, unsigned int *hash)
{
	str cid;
	if(msg == NULL || hash == NULL) {
		LM_ERR("bad parameters\n");
		return -1;
	}

	if(msg->callid == NULL
			&& ((parse_headers(msg, HDR_CALLID_F, 0) == -1)
					|| (msg->callid == NULL))) {
		LM_ERR("cannot parse Call-Id\n");
		return -1;
	}

	cid.s = msg->callid->body.s;
	cid.len = msg->callid->body.len;
	trim(&cid);

	*hash = ds_get_hash(&cid, NULL);

	return 0;
}


/**
 *
 */
int ds_hash_ruri(struct sip_msg *msg, unsigned int *hash)
{
	str *uri;
	str key1;
	str key2;

	if(msg == NULL || hash == NULL) {
		LM_ERR("bad parameters\n");
		return -1;
	}
	if(parse_sip_msg_uri(msg) < 0) {
		LM_ERR("bad request uri\n");
		return -1;
	}

	uri = GET_RURI(msg);
	if(get_uri_hash_keys(&key1, &key2, uri, &msg->parsed_uri, ds_flags) < 0)
		return -1;

	*hash = ds_get_hash(&key1, &key2);
	return 0;
}

/**
 *
 */
int ds_hash_authusername(struct sip_msg *msg, unsigned int *hash)
{
	/* Header, which contains the authorization */
	struct hdr_field *h = 0;
	/* The Username */
	str username = {0, 0};
	/* The Credentials from this request */
	auth_body_t *cred;

	if(msg == NULL || hash == NULL) {
		LM_ERR("bad parameters\n");
		return -1;
	}
	*hash = 0;
	if(parse_headers(msg, HDR_PROXYAUTH_F, 0) == -1) {
		LM_ERR("error parsing headers!\n");
		return -1;
	}
	if(msg->proxy_auth && !msg->proxy_auth->parsed) {
		if(parse_credentials(msg->proxy_auth) != 0) {
			LM_DBG("no parsing for proxy-auth header\n");
		}
	}
	if(msg->proxy_auth && msg->proxy_auth->parsed) {
		h = msg->proxy_auth;
	}
	if(!h) {
		if(parse_headers(msg, HDR_AUTHORIZATION_F, 0) == -1) {
			LM_ERR("error parsing headers!\n");
			return -1;
		}
		if(msg->authorization && !msg->authorization->parsed) {
			if(parse_credentials(msg->authorization) != 0) {
				LM_DBG("no parsing for auth header\n");
			}
		}
		if(msg->authorization && msg->authorization->parsed) {
			h = msg->authorization;
		}
	}
	if(!h) {
		LM_DBG("No Authorization-Header!\n");
		return 1;
	}

	cred = (auth_body_t *)(h->parsed);
	if(!cred || !cred->digest.username.user.len) {
		LM_ERR("No Authorization-Username or Credentials!\n");
		return 1;
	}

	username.s = cred->digest.username.user.s;
	username.len = cred->digest.username.user.len;

	trim(&username);

	*hash = ds_get_hash(&username, NULL);

	return 0;
}


/**
 *
 */
int ds_hash_pvar(struct sip_msg *msg, unsigned int *hash)
{
	/* The String to create the hash */
	str hash_str = {0, 0};

	if(msg == NULL || hash == NULL || hash_param_model == NULL) {
		LM_ERR("bad parameters\n");
		return -1;
	}
	if(pv_printf_s(msg, hash_param_model, &hash_str) < 0) {
		LM_ERR("error - cannot print the format\n");
		return -1;
	}

	/* Remove empty spaces */
	trim(&hash_str);
	if(hash_str.len <= 0) {
		LM_ERR("String is empty!\n");
		return -1;
	}

	*hash = ds_get_hash(&hash_str, NULL);
	LM_DBG("Hashing of '%.*s' resulted in %u !\n", hash_str.len, hash_str.s,
			*hash);

	return 0;
}

/*
 * Check if a destination set exists
 */
int ds_list_exist(int set)
{
	ds_set_t *si = NULL;
	LM_DBG("looking for destination set [%d]\n", set);

	/* get the index of the set */
	si = ds_avl_find(_ds_list, set);

	if(si == NULL) {
		LM_DBG("destination set [%d] not found\n", set);
		return -1; /* False */
	}
	LM_DBG("destination set [%d] found\n", set);
	return 1; /* True */
}

/*
 * Return a destination set
 */
ds_set_t *ds_list_lookup(int set)
{
	ds_set_t *si = NULL;
	LM_DBG("looking for destination set [%d]\n", set);

	/* get the index of the set */
	si = ds_avl_find(_ds_list, set);

	if(si == NULL) {
		LM_DBG("destination set [%d] not found\n", set);
		return NULL;
	}
	LM_DBG("destination set [%d] found\n", set);
	return si;
}

/**
 *
 */
int ds_get_leastloaded(ds_set_t *dset)
{
	int j;
	int k;
	int t;

	k = -1;
	t = 0x7fffffff; /* high load */
	lock_get(&dset->lock);
	for(j = 0; j < dset->nr; j++) {
		if(!ds_skip_dst(dset->dlist[j].flags)
				&& (dset->dlist[j].attrs.maxload == 0
						|| dset->dlist[j].dload
								   < dset->dlist[j].attrs.maxload)) {
			if(dset->dlist[j].dload < t) {
				k = j;
				t = dset->dlist[k].dload;
			}
		}
	}
	lock_release(&dset->lock);
	return k;
}

/**
 *
 */
int ds_load_add(struct sip_msg *msg, ds_set_t *dset, int setid, int dst)
{
	if(dset->dlist[dst].attrs.duid.len == 0) {
		LM_ERR("dst unique id not set for %d (%.*s)\n", setid,
				msg->callid->body.len, msg->callid->body.s);
		return -1;
	}

	if(ds_add_cell(_dsht_load, &msg->callid->body, &dset->dlist[dst].attrs.duid,
			   setid)
			< 0) {
		LM_ERR("cannot add load to %d (%.*s)\n", setid, msg->callid->body.len,
				msg->callid->body.s);
		return -1;
	}
	DS_LOAD_INC(dset, dst);
	return 0;
}

/**
 *
 */
int ds_load_replace(struct sip_msg *msg, str *duid)
{
	ds_cell_t *it;
	int set;
	int olddst;
	int newdst;
	ds_set_t *idx = NULL;
	int i;

	if(duid->len <= 0) {
		LM_ERR("invalid dst unique id not set for (%.*s)\n",
				msg->callid->body.len, msg->callid->body.s);
		return -1;
	}

	if((it = ds_get_cell(_dsht_load, &msg->callid->body)) == NULL) {
		LM_ERR("cannot find load for (%.*s)\n", msg->callid->body.len,
				msg->callid->body.s);
		return -1;
	}
	set = it->dset;
	/* get the index of the set */
	if(ds_get_index(set, *ds_crt_idx, &idx) != 0) {
		ds_unlock_cell(_dsht_load, &msg->callid->body);
		LM_ERR("destination set [%d] not found\n", set);
		return -1;
	}
	olddst = -1;
	newdst = -1;
	for(i = 0; i < idx->nr; i++) {
		if(idx->dlist[i].attrs.duid.len == it->duid.len
				&& strncasecmp(
						   idx->dlist[i].attrs.duid.s, it->duid.s, it->duid.len)
						   == 0) {
			olddst = i;
			if(newdst != -1)
				break;
		}
		if(idx->dlist[i].attrs.duid.len == duid->len
				&& strncasecmp(idx->dlist[i].attrs.duid.s, duid->s, duid->len)
						   == 0) {
			newdst = i;
			if(olddst != -1)
				break;
		}
	}
	/* old destination has not been found: has been removed meanwhile? */
	if(olddst == -1) {
		LM_WARN("old destination address not found for [%d, %.*s]\n", set,
				it->duid.len, it->duid.s);
	}
	if(newdst == -1) {
		/* new destination has not been found: has been removed meanwhile? */
		ds_unlock_cell(_dsht_load, &msg->callid->body);
		LM_ERR("new destination address not found for [%d, %.*s]\n", set,
				duid->len, duid->s);
		return -2;
	}

	ds_unlock_cell(_dsht_load, &msg->callid->body);
	ds_del_cell(_dsht_load, &msg->callid->body);

	if(olddst != -1)
		DS_LOAD_DEC(idx, olddst);

	if(ds_load_add(msg, idx, set, newdst) < 0) {
		LM_ERR("unable to replace destination load [%.*s / %.*s]\n", duid->len,
				duid->s, msg->callid->body.len, msg->callid->body.s);
		return -1;
	}
	return 0;
}

/**
 *
 */
int ds_load_remove_byid(int set, str *duid)
{
	int olddst;
	ds_set_t *idx = NULL;
	int i;

	/* get the index of the set */
	if(ds_get_index(set, *ds_crt_idx, &idx) != 0) {
		LM_ERR("destination set [%d] not found\n", set);
		return -1;
	}
	olddst = -1;
	for(i = 0; i < idx->nr; i++) {
		if(idx->dlist[i].attrs.duid.len == duid->len
				&& strncasecmp(idx->dlist[i].attrs.duid.s, duid->s, duid->len)
						   == 0) {
			olddst = i;
			break;
		}
	}
	if(olddst == -1) {
		LM_ERR("old destination address not found for [%d, %.*s]\n", set,
				duid->len, duid->s);
		return -1;
	}

	DS_LOAD_DEC(idx, olddst);

	return 0;
}

/**
 *
 */
int ds_load_remove(struct sip_msg *msg)
{
	ds_cell_t *it;

	if((it = ds_get_cell(_dsht_load, &msg->callid->body)) == NULL) {
		LM_ERR("cannot find load for (%.*s)\n", msg->callid->body.len,
				msg->callid->body.s);
		return -1;
	}

	if(ds_load_remove_byid(it->dset, &it->duid) < 0) {
		ds_unlock_cell(_dsht_load, &msg->callid->body);
		return -1;
	}
	ds_unlock_cell(_dsht_load, &msg->callid->body);
	ds_del_cell(_dsht_load, &msg->callid->body);

	return 0;
}

/**
 *
 */
int ds_load_state(struct sip_msg *msg, int state)
{
	ds_cell_t *it;

	if((it = ds_get_cell(_dsht_load, &msg->callid->body)) == NULL) {
		LM_DBG("cannot find load for (%.*s)\n", msg->callid->body.len,
				msg->callid->body.s);
		return -1;
	}

	it->state = state;
	ds_unlock_cell(_dsht_load, &msg->callid->body);

	return 0;
}


/**
 *
 */
int ds_load_update(struct sip_msg *msg)
{
	if(parse_headers(msg, HDR_CSEQ_F | HDR_CALLID_F, 0) != 0
			|| msg->cseq == NULL || msg->callid == NULL) {
		LM_ERR("cannot parse cseq and callid headers\n");
		return -1;
	}
	if(msg->first_line.type == SIP_REQUEST) {
		if(msg->first_line.u.request.method_value == METHOD_BYE
				|| msg->first_line.u.request.method_value == METHOD_CANCEL) {
			/* off-load call */
			ds_load_remove(msg);
		}
		return 0;
	}

	if(get_cseq(msg)->method_id == METHOD_INVITE) {
		/* if status is 2xx then set state to confirmed */
		if(REPLY_CLASS(msg) == 2)
			ds_load_state(msg, DS_LOAD_CONFIRMED);
	}
	return 0;
}

/**
 *
 */
int ds_load_unset(struct sip_msg *msg)
{
	sr_xavp_t *rxavp = NULL;

	if(ds_xavp_dst.len <= 0)
		return 0;

	/* for INVITE requests should be called after dst list is built */
	if(msg->first_line.type == SIP_REQUEST
			&& msg->first_line.u.request.method_value == METHOD_INVITE) {
		rxavp = xavp_get_child_with_sval(&ds_xavp_dst, &ds_xavp_dst_dstid);
		if(rxavp == NULL)
			return 0;
	}
	return ds_load_remove(msg);
}

/**
 *
 */
static inline int ds_push_dst(
		sip_msg_t *msg, str *uri, socket_info_t *sock, int mode)
{
	struct action act;
	struct run_act_ctx ra_ctx;
	switch(mode) {
		case DS_SETOP_RURI:
			memset(&act, '\0', sizeof(act));
			act.type = SET_HOSTALL_T;
			act.val[0].type = STRING_ST;
			if(uri->len > 4 && strncasecmp(uri->s, "sip:", 4) == 0) {
				act.val[0].u.string = uri->s + 4;
			} else if(uri->len > 5 && strncasecmp(uri->s, "sips:", 5) == 0) {
				act.val[0].u.string = uri->s + 5;
			} else {
				act.val[0].u.string = uri->s;
			}
			init_run_actions_ctx(&ra_ctx);
			if(do_action(&ra_ctx, &act, msg) < 0) {
				LM_ERR("error while setting r-uri domain with: %.*s\n",
						uri->len, uri->s);
				return -1;
			}
			break;

		case DS_SETOP_XAVP:
			/* no update to d-uri/r-uri */
			return 0;

		default:
			if(set_dst_uri(msg, uri) < 0) {
				LM_ERR("error while setting dst uri with: %.*s\n", uri->len,
						uri->s);
				return -1;
			}
			/* dst_uri changes, so it makes sense to re-use the current uri for
			 * forking */
			ruri_mark_new(); /* re-use uri for serial forking */
			break;
	}
	if(sock) {
		LM_DBG("set send socket to %.*s\n", sock->sock_str.len,
				sock->sock_str.s);
		set_force_socket(msg, sock);
	}
	return 0;
}

/**
 *
 */
int ds_add_branches(sip_msg_t *msg, ds_set_t *idx, unsigned int hash, int mode)
{
	unsigned int i = 0;
	str ruri = STR_NULL;
	sip_uri_t *puri = NULL;
	char buri[MAX_URI_SIZE];

	if(mode != DS_SETOP_XAVP && hash + 1 >= idx->nr) {
		/* nothing to add */
		return 0;
	}

	if(mode == DS_SETOP_RURI) {
		/* ruri updates */
		LM_DBG("adding branches with ruri\n");
		if(parse_sip_msg_uri(msg) < 0) {
			LM_ERR("failed to parse sip msg uri\n");
			return -1;
		}
		puri = &msg->parsed_uri;
	} else {
		/* duri updates */
		LM_DBG("adding branches with duri\n");
	}
	if(mode != DS_SETOP_XAVP) {
		i = hash + 1;
	} else {
		i = hash;
	}
	for(; i < idx->nr; i++) {
		if(mode == DS_SETOP_RURI) {
			/* ruri updates */
			if(puri->user.len <= 0) {
				/* no username to preserve */
				if(append_branch(msg, &idx->dlist[i].uri, NULL, NULL,
						   Q_UNSPECIFIED, 0, idx->dlist[i].sock, NULL, 0, NULL,
						   NULL)
						< 0) {
					LM_ERR("failed to add branch with ruri\n");
					return -1;
				}
			} else {
				/* new uri from ruri username and dispatcher uri */
				if(idx->dlist[i].uri.len < 6) {
					LM_WARN("invalid dispatcher uri - skipping (%u)\n", i);
					continue;
				}
				if(strncmp(idx->dlist[i].uri.s, "sips:", 5) == 0) {
					ruri.len = snprintf(buri, MAX_URI_SIZE, "sips:%.*s@%.*s",
							puri->user.len, puri->user.s,
							idx->dlist[i].uri.len - 5, idx->dlist[i].uri.s + 5);
				} else {
					if(strncmp(idx->dlist[i].uri.s, "sip:", 4) == 0) {
						ruri.len = snprintf(buri, MAX_URI_SIZE, "sip:%.*s@%.*s",
								puri->user.len, puri->user.s,
								idx->dlist[i].uri.len - 4,
								idx->dlist[i].uri.s + 4);
					} else {
						LM_WARN("unsupported protocol schema - ignoring\n");
						continue;
					}
				}
				ruri.s = buri;
				if(append_branch(msg, &ruri, NULL, NULL, Q_UNSPECIFIED, 0,
						   idx->dlist[i].sock, NULL, 0, NULL, NULL)
						< 0) {
					LM_ERR("failed to add branch with user ruri\n");
					return -1;
				}
			}
		} else {
			/* duri updates */
			if(append_branch(msg, GET_RURI(msg), &idx->dlist[i].uri, NULL,
					   Q_UNSPECIFIED, 0, idx->dlist[i].sock, NULL, 0, NULL,
					   NULL)
					< 0) {
				LM_ERR("failed to add branch with duri\n");
				return -1;
			}
		}
	}
	return 0;
}

/**
 *
 */
int ds_add_xavp_record(
		ds_set_t *dsidx, int pos, int set, int alg, sr_xavp_t **pxavp)
{
	sr_xavp_t *nxavp = NULL;
	sr_xval_t nxval;

	/* add destination uri field */
	memset(&nxval, 0, sizeof(sr_xval_t));
	nxval.type = SR_XTYPE_STR;
	nxval.v.s = dsidx->dlist[pos].uri;
	if(xavp_add_value(&ds_xavp_dst_addr, &nxval, &nxavp) == NULL) {
		LM_ERR("failed to add destination uri xavp field\n");
		return -1;
	}

	/* add setid field */
	memset(&nxval, 0, sizeof(sr_xval_t));
	nxval.type = SR_XTYPE_LONG;
	nxval.v.l = set;
	if(xavp_add_value(&ds_xavp_dst_grp, &nxval, &nxavp) == NULL) {
		xavp_destroy_list(&nxavp);
		LM_ERR("failed to add destination setid xavp field\n");
		return -1;
	}

	if(((ds_xavp_dst_mode & DS_XAVP_DST_SKIP_ATTRS) == 0)
			&& (dsidx->dlist[pos].attrs.body.len > 0)) {
		memset(&nxval, 0, sizeof(sr_xval_t));
		nxval.type = SR_XTYPE_STR;
		nxval.v.s = dsidx->dlist[pos].attrs.body;
		if(xavp_add_value(&ds_xavp_dst_attrs, &nxval, &nxavp) == NULL) {
			xavp_destroy_list(&nxavp);
			LM_ERR("failed to add destination attrs xavp field\n");
			return -1;
		}
	}

	if(dsidx->dlist[pos].sock) {
		memset(&nxval, 0, sizeof(sr_xval_t));
		nxval.type = SR_XTYPE_VPTR;
		nxval.v.vptr = dsidx->dlist[pos].sock;
		if(xavp_add_value(&ds_xavp_dst_sock, &nxval, &nxavp) == NULL) {
			xavp_destroy_list(&nxavp);
			LM_ERR("failed to add destination sock xavp field\n");
			return -1;
		}
		if((ds_xavp_dst_mode & DS_XAVP_DST_ADD_SOCKSTR)
				&& (dsidx->dlist[pos].attrs.socket.len > 0)) {
			memset(&nxval, 0, sizeof(sr_xval_t));
			nxval.type = SR_XTYPE_STR;
			nxval.v.s = dsidx->dlist[pos].attrs.socket;
			if(xavp_add_value(&ds_xavp_dst_socket, &nxval, &nxavp) == NULL) {
				xavp_destroy_list(&nxavp);
				LM_ERR("failed to add socket address attrs xavp field\n");
				return -1;
			}
		}
		if((ds_xavp_dst_mode & DS_XAVP_DST_ADD_SOCKNAME)
				&& (dsidx->dlist[pos].attrs.sockname.len > 0)) {
			memset(&nxval, 0, sizeof(sr_xval_t));
			nxval.type = SR_XTYPE_STR;
			nxval.v.s = dsidx->dlist[pos].attrs.sockname;
			if(xavp_add_value(&ds_xavp_dst_sockname, &nxval, &nxavp) == NULL) {
				xavp_destroy_list(&nxavp);
				LM_ERR("failed to add socket name attrs xavp field\n");
				return -1;
			}
		}
	}

	if(alg == DS_ALG_CALLLOAD) {
		if(dsidx->dlist[pos].attrs.duid.len <= 0) {
			LM_ERR("no uid for destination: %d %.*s\n", set,
					dsidx->dlist[pos].uri.len, dsidx->dlist[pos].uri.s);
			xavp_destroy_list(&nxavp);
			return -1;
		}
		memset(&nxval, 0, sizeof(sr_xval_t));
		nxval.type = SR_XTYPE_STR;
		nxval.v.s = dsidx->dlist[pos].attrs.duid;
		if(xavp_add_value(&ds_xavp_dst_dstid, &nxval, &nxavp) == NULL) {
			xavp_destroy_list(&nxavp);
			LM_ERR("failed to add destination dst uid xavp field\n");
			return -1;
		}
	}

	/* add xavp in root list */
	memset(&nxval, 0, sizeof(sr_xval_t));
	nxval.type = SR_XTYPE_XAVP;
	nxval.v.xavp = nxavp;
	if((*pxavp = xavp_add_value_after(&ds_xavp_dst, &nxval, *pxavp)) == NULL) {
		LM_ERR("cannot add dst xavp to root list\n");
		xavp_destroy_list(&nxavp);
		return -1;
	}

	return 0;
}

/**
 *
 */
int ds_select_dst(struct sip_msg *msg, int set, int alg, int mode)
{
	return ds_select_dst_limit(msg, set, alg, 0, mode);
}

/**
 * Set destination address from group 'set' selected with alogorithm 'alg'
 * - the rest of addresses in group are added as next destination in xavps,
 *   up to the 'limit'
 * - mode specify to set address in R-URI or outbound proxy
 *
 */
int ds_select_dst_limit(
		sip_msg_t *msg, int set, int alg, uint32_t limit, int mode)
{
	int ret;
	sr_xval_t nxval;
	ds_select_state_t vstate;

	memset(&vstate, 0, sizeof(ds_select_state_t));
	vstate.setid = set;
	vstate.alg = alg;
	vstate.umode = mode;
	vstate.limit = limit;

	if(vstate.limit == 0) {
		LM_DBG("Limit set to 0 - forcing to unlimited\n");
		vstate.limit = 0xffffffff;
	}

	ret = ds_manage_routes(msg, &vstate);
	if(ret < 0) {
		return ret;
	}

	/* add cnt value to xavp */
	if(((ds_xavp_ctx_mode & DS_XAVP_CTX_SKIP_CNT) == 0)
			&& (ds_xavp_ctx.len >= 0)) {
		/* add to xavp the number of selected dst records */
		memset(&nxval, 0, sizeof(sr_xval_t));
		nxval.type = SR_XTYPE_LONG;
		nxval.v.l = vstate.cnt;
		if(xavp_add_xavp_value(&ds_xavp_ctx, &ds_xavp_ctx_cnt, &nxval, NULL)
				== NULL) {
			LM_ERR("failed to add cnt value to xavp\n");
			return -1;
		}
	}

	LM_DBG("selected target destinations: %d\n", vstate.cnt);

	return ret;
}

typedef struct sorted_ds
{
	int idx;
	int priority;
	int flags;
	ds_dest_t *dest;
} sorted_ds_t;

int ds_manage_routes_fill_reordered_xavp(
		sorted_ds_t *ds_sorted, ds_set_t *idx, ds_select_state_t *rstate)
{
	int i;
	if(!(ds_flags & DS_FAILOVER_ON))
		return 1;
	for(i = 0; i < idx->nr && rstate->cnt < rstate->limit; i++) {

		if(ds_sorted[i].idx < 0 || ds_skip_dst(ds_sorted[i].flags)
				|| (ds_use_default != 0 && ds_sorted[i].idx == (idx->nr - 1))) {
			LM_DBG("[%d|%.*s|idx:%d]skipped %d || %d\n", i,
					ds_sorted[i].dest->uri.len, ds_sorted[i].dest->uri.s,
					ds_sorted[i].idx, ds_sorted[i].idx < 0,
					ds_skip_dst(ds_sorted[i].flags));
			continue;
		}
		if(ds_add_xavp_record(idx, ds_sorted[i].idx, rstate->setid, rstate->alg,
				   &rstate->lxavp)
				< 0) {
			LM_ERR("failed to add destination in the xavp (%d/%d)\n",
					ds_sorted[i].idx, rstate->setid);
			return -1;
		}
		LM_DBG("destination added in the xavp (%d/%d)\n", ds_sorted[i].idx,
				rstate->setid);
		rstate->cnt++;
	}
	return 0;
}

int ds_manage_routes_fill_xavp(
		unsigned int hash, ds_set_t *idx, ds_select_state_t *rstate)
{
	int i;

	LM_DBG("using first entry [%d/%d]\n", rstate->setid, hash);
	if(ds_add_xavp_record(idx, hash, rstate->setid, rstate->alg, &rstate->lxavp)
			< 0) {
		LM_ERR("failed to add destination in the xavp (%d/%d)\n", hash,
				rstate->setid);
		return -1;
	}
	rstate->cnt++;

	/* add to xavp the destinations after the selected one */
	for(i = hash + 1; i < idx->nr && rstate->cnt < rstate->limit; i++) {
		if(ds_skip_dst(idx->dlist[i].flags)
				|| (ds_use_default != 0 && i == (idx->nr - 1))) {
			continue;
		}
		/* max load exceeded per destination */
		if(rstate->alg == DS_ALG_CALLLOAD && idx->dlist[i].attrs.maxload != 0
				&& idx->dlist[i].dload >= idx->dlist[i].attrs.maxload) {
			continue;
		}
		LM_DBG("using entry [%d/%d]\n", rstate->setid, i);
		if(ds_add_xavp_record(
				   idx, i, rstate->setid, rstate->alg, &rstate->lxavp)
				< 0) {
			LM_ERR("failed to add destination in the xavp (%d/%d)\n", i,
					rstate->setid);
			return -1;
		}
		rstate->cnt++;
	}

	/* add to xavp the destinations before the selected one */
	for(i = 0; i < hash && rstate->cnt < rstate->limit; i++) {
		if(ds_skip_dst(idx->dlist[i].flags)
				|| (ds_use_default != 0 && i == (idx->nr - 1))) {
			continue;
		}
		/* max load exceeded per destination */
		if(rstate->alg == DS_ALG_CALLLOAD && idx->dlist[i].attrs.maxload != 0
				&& idx->dlist[i].dload >= idx->dlist[i].attrs.maxload) {
			continue;
		}
		LM_DBG("using entry [%d/%d]\n", rstate->setid, i);
		if(ds_add_xavp_record(
				   idx, i, rstate->setid, rstate->alg, &rstate->lxavp)
				< 0) {
			LM_ERR("failed to add destination in the xavp (%d/%d)\n", i,
					rstate->setid);
			return -1;
		}
		rstate->cnt++;
	}
	return 0;
}


void ds_sorted_by_priority(sorted_ds_t *sorted_ds, int size)
{
	int i, ii;

	for(i = 0; i < size; ++i) {
		for(ii = 1; ii < size; ++ii) {
			sorted_ds_t temp;
			if(sorted_ds[ii - 1].priority < sorted_ds[ii].priority) {
				temp.idx = sorted_ds[ii].idx;
				temp.priority = sorted_ds[ii].priority;
				temp.flags = sorted_ds[ii].flags;
				temp.dest = sorted_ds[ii].dest;
				sorted_ds[ii].idx = sorted_ds[ii - 1].idx;
				sorted_ds[ii].priority = sorted_ds[ii - 1].priority;
				sorted_ds[ii].flags = sorted_ds[ii - 1].flags;
				sorted_ds[ii].dest = sorted_ds[ii - 1].dest;
				sorted_ds[ii - 1].idx = temp.idx;
				sorted_ds[ii - 1].priority = temp.priority;
				sorted_ds[ii - 1].flags = temp.flags;
				sorted_ds[ii - 1].dest = temp.dest;
			}
		}
	}
}

int ds_manage_route_algo13(ds_set_t *idx, ds_select_state_t *rstate)
{
	int hash = idx->last;
	int y = 0;
	int z = hash;
	int active_priority = 0;
	sorted_ds_t *ds_sorted = pkg_malloc(sizeof(sorted_ds_t) * idx->nr);
	if(ds_sorted == NULL) {
		PKG_MEM_ERROR;
		return -1;
	}

	for(y = 0; y < idx->nr; y++) {
		int latency_priority_handicap = 0;
		ds_dest_t *ds_dest = &idx->dlist[z];
		int gw_priority = ds_dest->priority;
		int gw_latency = ds_dest->latency_stats.estimate;
		int gw_inactive = ds_skip_dst(ds_dest->flags);
		// if cc is enabled, the latency is the congestion ms instead of the estimated latency.
		if(ds_dest->attrs.congestion_control)
			gw_latency = ds_dest->latency_stats.estimate
						 - ds_dest->latency_stats.average;
		if(!gw_inactive) {
			if(gw_latency > gw_priority && gw_priority > 0)
				latency_priority_handicap = gw_latency / gw_priority;
			ds_dest->attrs.rpriority = gw_priority - latency_priority_handicap;
			if(ds_dest->attrs.rpriority < 1 && gw_priority > 0)
				ds_dest->attrs.rpriority = 1;
			ds_sorted[y].idx = z;
			ds_sorted[y].priority = ds_dest->attrs.rpriority;
			LM_DBG("[active][%d]idx[%d]uri[%.*s]priority[%d-%d=%d]latency[%dms]"
				   "flag[%d]\n",
					y, z, ds_dest->uri.len, ds_dest->uri.s, gw_priority,
					latency_priority_handicap, ds_dest->attrs.rpriority,
					gw_latency, ds_dest->flags);
		} else {
			ds_sorted[y].idx = -1;
			ds_sorted[y].priority = -1;
			LM_DBG("[inactive][%d]idx[%d]uri[%.*s]priority[%d]latency[%dms]"
				   "flag[%d]\n",
					y, -1, ds_dest->uri.len, ds_dest->uri.s, gw_priority,
					gw_latency, ds_dest->flags);
		}
		ds_sorted[y].flags = ds_dest->flags;
		ds_sorted[y].dest = ds_dest;

		if(ds_use_default != 0 && idx->nr != 1)
			z = (z + 1) % (idx->nr - 1);
		else
			z = (z + 1) % idx->nr;
	}
	ds_sorted_by_priority(ds_sorted, idx->nr);
	// the list order might have changed after sorting - update hash
	if(idx->nr > 0) {
		hash = ds_sorted[0].idx;
		active_priority = ds_sorted[0].priority;
	}
	ds_manage_routes_fill_reordered_xavp(ds_sorted, idx, rstate);
	idx->last = (hash + 1) % idx->nr;
	LM_DBG("priority[%d]gateway_selected[%d]next_index[%d]\n", active_priority,
			hash, idx->last);
	pkg_free(ds_sorted);
	return hash;
}

/**
 *
 */
int ds_manage_routes(sip_msg_t *msg, ds_select_state_t *rstate)
{
	int i;
	unsigned int hash;
	ds_set_t *idx = NULL;
	int ulast = 0;
	int vlast = 0;
	int xavp_filled = 0;

	if(msg == NULL) {
		LM_ERR("bad parameters\n");
		return -1;
	}

	if(_ds_list == NULL || _ds_list_nr <= 0) {
		LM_ERR("no destination sets\n");
		return -1;
	}

	if((rstate->umode == DS_SETOP_DSTURI) && (ds_force_dst == 0)
			&& (msg->dst_uri.s != NULL || msg->dst_uri.len > 0)) {
		LM_ERR("destination already set [%.*s]\n", msg->dst_uri.len,
				msg->dst_uri.s);
		return -1;
	}


	/* get the index of the set */
	if(ds_get_index(rstate->setid, *ds_crt_idx, &idx) != 0) {
		LM_ERR("destination set [%d] not found\n", rstate->setid);
		return -1;
	}

	LM_DBG("set [%d]\n", rstate->setid);

	hash = 0;
	switch(rstate->alg) {
		case DS_ALG_HASHCALLID: /* 0 - hash call-id */
			if(ds_hash_callid(msg, &hash) != 0) {
				LM_ERR("can't get callid hash\n");
				return -1;
			}
			break;
		case DS_ALG_HASHFROMURI: /* 1 - hash from-uri */
			if(ds_hash_fromuri(msg, &hash) != 0) {
				LM_ERR("can't get From uri hash\n");
				return -1;
			}
			break;
		case DS_ALG_HASHTOURI: /* 2 - hash to-uri */
			if(ds_hash_touri(msg, &hash) != 0) {
				LM_ERR("can't get To uri hash\n");
				return -1;
			}
			break;
		case DS_ALG_HASHRURI: /* 3 - hash r-uri */
			if(ds_hash_ruri(msg, &hash) != 0) {
				LM_ERR("can't get ruri hash\n");
				return -1;
			}
			break;
		case DS_ALG_ROUNDROBIN: /* 4 - round robin */
			lock_get(&idx->lock);
			hash = idx->last;
			idx->last = (idx->last + 1) % idx->nr;
			vlast = idx->last;
			lock_release(&idx->lock);
			ulast = 1;
			break;
		case DS_ALG_HASHAUTHUSER: /* 5 - hash auth username */
			i = ds_hash_authusername(msg, &hash);
			switch(i) {
				case 0:
					/* Authorization-Header found: Nothing to be done here */
					break;
				case 1:
					/* No Authorization found: Use round robin */
					lock_get(&idx->lock);
					hash = idx->last;
					idx->last = (idx->last + 1) % idx->nr;
					vlast = idx->last;
					lock_release(&idx->lock);
					ulast = 1;
					break;
				default:
					LM_ERR("can't get authorization hash\n");
					return -1;
			}
			break;
		case DS_ALG_RANDOM: /* 6 - random selection */
			hash = kam_rand();
			break;
		case DS_ALG_HASHPV: /* 7 - hash on PV value */
			if(ds_hash_pvar(msg, &hash) != 0) {
				LM_ERR("can't get PV hash\n");
				return -1;
			}
			break;
		case DS_ALG_SERIAL: /* 8 - use always first entry */
			hash = 0;
			break;
		case DS_ALG_WEIGHT: /* 9 - weight based distribution */
			lock_get(&idx->lock);
			hash = idx->wlist[idx->wlast];
			idx->wlast = (idx->wlast + 1) % 100;
			lock_release(&idx->lock);
			break;
		case DS_ALG_CALLLOAD: /* 10 - call load based distribution */
			/* only INVITE can start a call */
			if(msg->first_line.u.request.method_value != METHOD_INVITE) {
				/* use first entry */
				hash = 0;
				rstate->alg = 0;
				break;
			}
			if(ds_xavp_dst.len <= 0) {
				LM_ERR("no dst xavp for load distribution"
					   " - using first entry...\n");
				hash = 0;
				rstate->alg = 0;
			} else {
				i = ds_get_leastloaded(idx);
				if(i < 0) {
					/* no address selected */
					return -1;
				}
				hash = i;
				if(ds_load_add(msg, idx, rstate->setid, hash) < 0) {
					LM_ERR("unable to update destination load"
						   " - classic dispatching\n");
					rstate->alg = 0;
				}
			}
			break;
		case DS_ALG_RELWEIGHT: /* 11 - relative weight based distribution */
			lock_get(&idx->lock);
			hash = idx->rwlist[idx->rwlast];
			idx->rwlast = (idx->rwlast + 1) % 100;
			lock_release(&idx->lock);
			break;
		case DS_ALG_PARALLEL: /* 12 - parallel dispatching */
			hash = 0;
			break;
		case DS_ALG_LATENCY: /* 13 - latency optimized round-robin with failover */
			lock_get(&idx->lock);
			hash = ds_manage_route_algo13(idx, rstate);
			lock_release(&idx->lock);
			if(hash == -1)
				return -1;
			xavp_filled = 1;
			break;
		case DS_ALG_OVERLOAD: /* 64 - round robin with overload control */
			lock_get(&idx->lock);
			hash = idx->last;
			idx->last = (idx->last + 1) % idx->nr;
			vlast = idx->last;
			lock_release(&idx->lock);
			ulast = 1;
			break;
		default:
			LM_WARN("algo %d not implemented - using first entry...\n",
					rstate->alg);
			hash = 0;
	}

	LM_DBG("using alg [%d] hash [%u]\n", rstate->alg, hash);

	if(ds_use_default != 0 && idx->nr != 1)
		hash = hash % (idx->nr - 1);
	else
		hash = hash % idx->nr;
	i = hash;

	/* if selected address is inactive, find next active */
	while(!xavp_filled
			&& (ds_skip_dst(idx->dlist[i].flags)
					|| ds_oc_skip(idx, rstate->alg, i))) {
		if(ds_use_default != 0 && idx->nr != 1)
			i = (i + 1) % (idx->nr - 1);
		else
			i = (i + 1) % idx->nr;
		if(i == hash) {
			/* back to start -- looks like no active dst */
			if(ds_use_default != 0) {
				i = idx->nr - 1;
				if(ds_skip_dst(idx->dlist[i].flags)
						|| ds_oc_skip(idx, rstate->alg, i))
					return -1;
				break;
			} else {
				return -1;
			}
		}
	}

	hash = i;

	if(rstate->umode != DS_SETOP_XAVP) {
		if(ds_push_dst(msg, &idx->dlist[hash].uri, idx->dlist[hash].sock,
				   rstate->umode)
				!= 0) {
			LM_ERR("cannot set next hop address with: %.*s\n",
					idx->dlist[hash].uri.len, idx->dlist[hash].uri.s);
			return -1;
		}
		rstate->emode = 1;
	}

	/* update last field for next select to point after the current active used,
	 * if not updated meanwhile */
	lock_get(&idx->lock);
	if(ulast && (vlast == idx->last)) {
		idx->last = (hash + 1) % idx->nr;
	}
	lock_release(&idx->lock);

	LM_DBG("selected [%d-%d-%d/%d] <%.*s>\n", rstate->alg, rstate->setid,
			rstate->umode, hash, idx->dlist[hash].uri.len,
			idx->dlist[hash].uri.s);

	if(rstate->alg == DS_ALG_PARALLEL) {
		if(ds_add_branches(msg, idx, hash, rstate->umode) < 0) {
			LM_ERR("failed to add additional branches\n");
			/* one destination was already set - return success anyhow */
			return 2;
		}
		return 1;
	}

	if(!(ds_flags & DS_FAILOVER_ON))
		return 1;

	if(ds_xavp_dst.len <= 0) {
		/* no xavp name to store the rest of the records */
		return 1;
	}

	if(!xavp_filled) {
		if(ds_manage_routes_fill_xavp(hash, idx, rstate) == -1) {
			return -1;
		}
	}

	/* add default dst to last position in XAVP list */
	if(ds_use_default != 0 && hash != idx->nr - 1
			&& rstate->cnt < rstate->limit) {
		LM_DBG("using default entry [%d/%d]\n", rstate->setid, idx->nr - 1);
		if(ds_add_xavp_record(
				   idx, idx->nr - 1, rstate->setid, rstate->alg, &rstate->lxavp)
				< 0) {
			LM_ERR("failed to add default destination in the xavp\n");
			return -1;
		}
		rstate->cnt++;
	}

	return 1;
}

int ds_update_dst(struct sip_msg *msg, int upos, int mode)
{

	int ret;
	socket_info_t *sock = NULL;
	sr_xavp_t *rxavp = NULL;
	sr_xavp_t *lxavp = NULL;

	LM_DBG("updating dst\n");
	if(upos == DS_USE_NEXT) {
		if(!(ds_flags & DS_FAILOVER_ON) || ds_xavp_dst.len <= 0) {
			LM_WARN("failover support disabled\n");
			return -1;
		}
	}

next_dst:
	rxavp = xavp_get(&ds_xavp_dst, NULL);
	if(rxavp == NULL || rxavp->val.type != SR_XTYPE_XAVP) {
		LM_DBG("no xavp with previous destination record\n");
		return -1;
	}

	if(upos == DS_USE_NEXT) {
		LM_DBG("updating dst with next record\n");
		/* use next destination - delete the current one and search the next */
		xavp_rm(rxavp, NULL);

		rxavp = xavp_get(&ds_xavp_dst, NULL);
		if(rxavp == NULL || rxavp->val.type != SR_XTYPE_XAVP) {
			LM_DBG("no xavp with next destination record\n");
			return -1;
		}
	}

	/* retrieve attributes from sub list */
	rxavp = rxavp->val.v.xavp;
	lxavp = xavp_get(&ds_xavp_dst_sock, rxavp);
	if(lxavp != NULL && lxavp->val.type == SR_XTYPE_VPTR) {
		LM_DBG("socket enforced in next destination record\n");
		sock = lxavp->val.v.vptr;
	}

	lxavp = xavp_get(&ds_xavp_dst_addr, rxavp);
	if(lxavp == NULL || lxavp->val.type != SR_XTYPE_STR) {
		LM_WARN("no xavp uri field in next destination record (%p)\n", lxavp);
		return -1;
	}

	if(ds_push_dst(msg, &lxavp->val.v.s, sock, mode) != 0) {
		LM_ERR("cannot set dst addr: %.*s\n", lxavp->val.v.s.len,
				lxavp->val.v.s.s);
		return -1;
	}
	LM_DBG("using next dst uri [%.*s]\n", lxavp->val.v.s.len, lxavp->val.v.s.s);

	/* call load update if dstid field is set */
	lxavp = xavp_get(&ds_xavp_dst_dstid, rxavp);
	if(lxavp == NULL || lxavp->val.type != SR_XTYPE_STR) {
		/* no dstid field - done */
		return 1;
	}
	if(upos == DS_USE_NEXT) {
		ret = ds_load_replace(msg, &lxavp->val.v.s);
		switch(ret) {
			case 0:
				break;
			case -2:
				LM_ERR("cannot update load with %.*s, skipping dst.\n",
						lxavp->val.v.s.len, lxavp->val.v.s.s);
				goto next_dst;
			default:
				LM_ERR("cannot update load distribution\n");
				return -1;
		}
	}
	return 1;
}

/* callback for adding nodes based on index */
void ds_add_dest_cb(ds_set_t *node, int i, void *arg)
{
	int setn;

	if(add_dest2list(node->id, node->dlist[i].uri, node->dlist[i].flags,
			   node->dlist[i].priority, &node->dlist[i].attrs.body,
			   *ds_next_idx, &setn, node->dlist[i].dload,
			   &node->dlist[i].latency_stats)
			!= 0) {
		LM_WARN("failed to add destination in group %d - %.*s\n", node->id,
				node->dlist[i].uri.len, node->dlist[i].uri.s);
	}
	return;
}

/* add dispatcher entry to in-memory dispatcher list */
int ds_add_dst(int group, str *address, int flags, int priority, str *attrs)
{
	int setn;

	setn = _ds_list_nr;

	*ds_next_idx = (*ds_crt_idx + 1) % 2;
	ds_avl_destroy(&ds_lists[*ds_next_idx]);

	// add all existing destinations
	ds_iter_set(_ds_list, &ds_add_dest_cb, NULL);

	// add new destination
	if(add_dest2list(group, *address, flags, priority, attrs, *ds_next_idx,
			   &setn, 0, NULL)
			!= 0) {
		LM_WARN("unable to add destination %.*s to set %d", address->len,
				address->s, group);
		if(ds_load_mode == 1) {
			goto error;
		}
	}

	if(reindex_dests(ds_lists[*ds_next_idx]) != 0) {
		LM_ERR("error on reindex\n");
		goto error;
	}

	_ds_list_nr = setn;
	*ds_crt_idx = *ds_next_idx;

	ds_log_sets();
	return 0;

error:
	ds_avl_destroy(&ds_lists[*ds_next_idx]);
	*ds_next_idx = *ds_crt_idx;
	return -1;
}

/* callback for removing nodes based on setid & address */
void ds_filter_dest_cb(ds_set_t *node, int i, void *arg)
{
	struct ds_filter_dest_cb_arg *filter_arg = (typeof(filter_arg))arg;

	if(node->id == filter_arg->setid
			&& node->dlist[i].uri.len == filter_arg->dest->uri.len
			&& strncmp(node->dlist[i].uri.s, filter_arg->dest->uri.s,
					   filter_arg->dest->uri.len)
					   == 0)
		return;

	if(add_dest2list(node->id, node->dlist[i].uri, node->dlist[i].flags,
			   node->dlist[i].priority, &node->dlist[i].attrs.body,
			   *ds_next_idx, filter_arg->setn, node->dlist[i].dload,
			   &node->dlist[i].latency_stats)
			!= 0) {
		LM_WARN("failed to add destination in group %d - %.*s\n", node->id,
				node->dlist[i].uri.len, node->dlist[i].uri.s);
	}
	return;
}

/* remove dispatcher entry from in-memory dispatcher list */
int ds_remove_dst(int group, str *address)
{
	int setn;
	struct ds_filter_dest_cb_arg filter_arg;
	ds_dest_t *dp = NULL;

	setn = 0;

	dp = pack_dest(*address, 0, 0, NULL, 0);
	if(dp == NULL) {
		LM_ERR("failed to pack address: %d %.*s\n", group, address->len,
				address->s);
		return -1;
	}
	filter_arg.setid = group;
	filter_arg.dest = dp;
	filter_arg.setn = &setn;

	*ds_next_idx = (*ds_crt_idx + 1) % 2;
	ds_avl_destroy(&ds_lists[*ds_next_idx]);

	// add existing destinations except destination that matches group & address
	ds_iter_set(_ds_list, &ds_filter_dest_cb, &filter_arg);

	if(reindex_dests(ds_lists[*ds_next_idx]) != 0) {
		LM_ERR("error on reindex\n");
		goto error;
	}

	_ds_list_nr = setn;
	*ds_crt_idx = *ds_next_idx;

	ds_log_sets();
	return 0;

error:
	ds_avl_destroy(&ds_lists[*ds_next_idx]);
	*ds_next_idx = *ds_crt_idx;
	return -1;
}

int ds_mark_dst(struct sip_msg *msg, int state)
{
	sr_xavp_t *rxavp = NULL;
	int group;
	int ret;
	ds_rctx_t rctx;

	if(!(ds_flags & DS_FAILOVER_ON)) {
		LM_WARN("failover support disabled\n");
		return -1;
	}

	if(ds_xavp_dst.len <= 0) {
		LM_WARN("no xavp name to store dst records\n");
		return -1;
	}
	rxavp = xavp_get_child_with_ival(&ds_xavp_dst, &ds_xavp_dst_grp);

	if(rxavp == NULL)
		return -1; /* grp xavp not available */
	group = (int)rxavp->val.v.l;

	rxavp = xavp_get_child_with_sval(&ds_xavp_dst, &ds_xavp_dst_addr);

	if(rxavp == NULL)
		return -1; /* dst addr uri not available */

	memset(&rctx, 0, sizeof(ds_rctx_t));
	if(msg != NULL) {
		if(msg != FAKED_REPLY) {
			if(msg->first_line.type == SIP_REPLY) {
				rctx.flags |= 1;
				rctx.code = (int)msg->first_line.u.reply.statuscode;
				rctx.reason = msg->first_line.u.reply.reason;
			} else {
				rctx.code = 820;
			}
		} else {
			rctx.code = 810;
		}
	} else {
		rctx.code = 800;
	}
	ret = ds_update_state(msg, group, &rxavp->val.v.s, state, &rctx);

	LM_DBG("state [%d] grp [%d] dst [%.*s]\n", state, group, rxavp->val.v.s.len,
			rxavp->val.v.s.s);

	return (ret == 0) ? 1 : -1;
}

void latency_stats_init(
		ds_latency_stats_t *latency_stats, int latency, int count)
{
	latency_stats->stdev = 0.0f;
	latency_stats->m2 = 0.0f;
	latency_stats->max = latency;
	latency_stats->min = latency;
	latency_stats->average = latency;
	latency_stats->estimate = latency;
	latency_stats->count = count;
}

ds_latency_stats_t *latency_stats_find(int group, str *address)
{

	int i = 0;
	ds_set_t *idx = NULL;

	if(_ds_list == NULL || _ds_list_nr <= 0) {
		LM_DBG("the list is null\n");
		return NULL;
	}

	/* get the index of the set */
	if(ds_get_index(group, *ds_crt_idx, &idx) != 0) {
		LM_DBG("destination set [%d] not found\n", group);
		return NULL;
	}

	while(i < idx->nr) {
		if(idx->dlist[i].uri.len == address->len
				&& strncasecmp(idx->dlist[i].uri.s, address->s, address->len)
						   == 0) {
			/* destination address found - copy current stats */
			return &idx->dlist[i].latency_stats;
		}
		i++;
	}

	return NULL;
}

#define _VOR1(v) ((v) ? (v) : 1)

static inline void latency_stats_update(
		ds_latency_stats_t *latency_stats, int latency)
{
	int training_count = 10000;

	/* after 2^21 ~24 days at 1s interval, the average becomes a weighted average */
	if(latency_stats->count < 2097152) {
		latency_stats->count++;
	} else { /* We adjust the sum of squares used by the oneline algorithm proportionally */
		latency_stats->m2 -= latency_stats->m2 / _VOR1(latency_stats->count);
	}

	if(latency_stats->count == 1)
		latency_stats_init(latency_stats, latency, 1);
	/* stabilize-train the estimator if the average is stable after 10 samples */
	if(latency_stats->count > 10 && latency_stats->count < training_count
			&& latency_stats->stdev < 0.5)
		latency_stats->count = training_count;

	if(latency_stats->min > latency)
		latency_stats->min = latency;
	if(latency_stats->max < latency)
		latency_stats->max = latency;

	/* standard deviation using oneline algorithm */
	/* https://en.wikipedia.org/wiki/Algorithms_for_calculating_variance#Online_algorithm */
	if(latency_stats->count > 1) {
		float delta;
		float delta2;
		delta = latency - latency_stats->average;
		latency_stats->average += delta / _VOR1(latency_stats->count);
		delta2 = latency - latency_stats->average;
		latency_stats->m2 += ((double)delta) * delta2;
		latency_stats->stdev =
				sqrt(latency_stats->m2 / _VOR1(latency_stats->count - 1));
	}
	/* exponentially weighted moving average */
	if(latency_stats->count < 10) {
		latency_stats->estimate = latency_stats->average;
	} else {
		latency_stats->estimate =
				latency_stats->estimate * ds_latency_estimator_alpha
				+ latency * (1 - ds_latency_estimator_alpha);
	}
}

typedef struct congestion_control_state
{
	int gw_congested_count;
	int gw_normal_count;
	int total_congestion_ms;
	int enabled;
	int apply_rweights;
} congestion_control_state_t;

int ds_update_weighted_congestion_control(congestion_control_state_t *cc,
		int weight, ds_latency_stats_t *latency_stats)
{
	int active_weight = 0;
	int congestion_ms = latency_stats->estimate - latency_stats->average;
	if(weight <= 0)
		return 0;
	if(congestion_ms < 0)
		congestion_ms = 0;
	cc->total_congestion_ms += congestion_ms;
	active_weight = weight - congestion_ms;
	if(active_weight < 0)
		active_weight = 0;
	if(active_weight == 0) {
		cc->gw_congested_count++;
	} else {
		cc->gw_normal_count++;
	}
	return active_weight;
}

void ds_init_congestion_control_state(congestion_control_state_t *cc)
{
	cc->gw_congested_count = 0;
	cc->gw_normal_count = 0;
	cc->total_congestion_ms = 0;
	cc->enabled = 1;
	cc->apply_rweights = 0;
}

int ds_update_latency(int group, str *address, int code)
{
	int i = 0;
	int state = 0;
	ds_set_t *idx = NULL;
	congestion_control_state_t cc;
	ds_init_congestion_control_state(&cc);

	if(_ds_list == NULL || _ds_list_nr <= 0) {
		LM_ERR("the list is null\n");
		return -1;
	}

	/* get the index of the set */
	if(ds_get_index(group, *ds_crt_idx, &idx) != 0) {
		LM_ERR("destination set [%d] not found\n", group);
		return -1;
	}
	lock_get(&idx->lock);
	while(i < idx->nr) {
		ds_dest_t *ds_dest = &idx->dlist[i];
		ds_latency_stats_t *latency_stats = &ds_dest->latency_stats;
		if(ds_dest->uri.len == address->len
				&& strncasecmp(ds_dest->uri.s, address->s, address->len) == 0) {
			struct timeval now;
			int latency_ms;
			/* Destination address found, this is the gateway that was pinged. */
			state = ds_dest->flags;
			if(!(state & DS_PROBING_DST)) {
				i++;
				continue;
			}
			if(code == 408 && latency_stats->timeout < UINT32_MAX)
				latency_stats->timeout++;

			if(latency_stats->start.tv_sec == 0
					&& latency_stats->start.tv_usec == 0) {
				/* If we don't have a start time, we can't calculate latency */
				i++;
				continue;
			}

			gettimeofday(&now, NULL);
			latency_ms = (now.tv_sec - latency_stats->start.tv_sec) * 1000
						 + (now.tv_usec - latency_stats->start.tv_usec) / 1000;
			if(code != 408)
				latency_stats_update(latency_stats, latency_ms);

			LM_DBG("[%d]latency[%d]avg[%.2f][%.*s]code[%d]rweight[%d]\n",
					latency_stats->count, latency_ms, latency_stats->average,
					address->len, address->s, code, ds_dest->attrs.rweight);

			/* Adjusting weight using congestion detection based on latency estimator. */
			if(ds_dest->attrs.congestion_control && ds_dest->attrs.weight > 0) {
				int active_weight = ds_update_weighted_congestion_control(
						&cc, ds_dest->attrs.weight, latency_stats);
				if(ds_dest->attrs.rweight != active_weight) {
					cc.apply_rweights = 1;
					ds_dest->attrs.rweight = active_weight;
				}
				LM_DBG("[%d]latency[%d]avg[%.2f][%.*s]code[%d]rweight[%d]cms[%"
					   "d]\n",
						latency_stats->count, latency_ms,
						latency_stats->average, address->len, address->s, code,
						ds_dest->attrs.rweight,
						ds_dest->attrs.weight - active_weight);
			}
		} else if(ds_dest->attrs.congestion_control
				  && ds_dest->attrs.weight > 0) {
			/* This is another gateway in the set, we verify if it is congested. */
			ds_update_weighted_congestion_control(
					&cc, ds_dest->attrs.weight, latency_stats);
		}
		if(!ds_dest->attrs.congestion_control)
			cc.enabled = 0;
		i++;
	}
	/* All the GWs are above their congestion threshold, load distribution will now be based on
	 * the ratio of congestion_ms each GW is facing. */
	if(cc.enabled && cc.gw_congested_count > 1 && cc.gw_normal_count == 0) {
		i = 0;
		while(i < idx->nr) {
			int congestion_ms;
			int active_weight;
			ds_dest_t *ds_dest = &idx->dlist[i];
			ds_latency_stats_t *latency_stats = &ds_dest->latency_stats;
			congestion_ms = latency_stats->estimate - latency_stats->average;
			/* We multiply by 2^4 to keep enough precision */
			active_weight =
					(cc.total_congestion_ms << 4) / _VOR1(congestion_ms);
			if(ds_dest->attrs.rweight != active_weight) {
				cc.apply_rweights = 1;
				ds_dest->attrs.rweight = active_weight;
			}
			LM_DBG("all gw "
				   "congested[%d][%d]latency_avg[%.2f][%.*s]code[%d]rweight[%d/"
				   "%d:%d]cms[%d]\n",
					cc.total_congestion_ms, latency_stats->count,
					latency_stats->average, ds_dest->uri.len, ds_dest->uri.s,
					code, cc.total_congestion_ms, congestion_ms,
					ds_dest->attrs.rweight, congestion_ms);
			i++;
		}
	}

	lock_release(&idx->lock);
	if(cc.enabled && cc.apply_rweights)
		dp_init_relative_weights(idx);
	return state;
}


/**
 * Get state for given destination
 */
int ds_get_state(int group, str *address)
{
	int i = 0;
	ds_set_t *idx = NULL;

	if(_ds_list == NULL || _ds_list_nr <= 0) {
		LM_ERR("the list is null\n");
		return -1;
	}

	/* get the index of the set */
	if(ds_get_index(group, *ds_crt_idx, &idx) != 0) {
		LM_ERR("destination set [%d] not found\n", group);
		return -1;
	}

	while(i < idx->nr) {
		if(idx->dlist[i].uri.len == address->len
				&& strncasecmp(idx->dlist[i].uri.s, address->s, address->len)
						   == 0) {
			/* destination address found */
			return idx->dlist[i].flags;
		}
		i++;
	}
	return 0;
}

/**
 * Update destionation's state
 */
int ds_update_state(
		sip_msg_t *msg, int group, str *address, int state, ds_rctx_t *rctx)
{
	int i = 0;
	int old_state = 0;
	int init_state = 0;
	ds_set_t *idx = NULL;

	if(_ds_list == NULL || _ds_list_nr <= 0) {
		LM_ERR("the list is null\n");
		return -1;
	}

	/* get the index of the set */
	if(ds_get_index(group, *ds_crt_idx, &idx) != 0) {
		LM_ERR("destination set [%d] not found\n", group);
		return -1;
	}
	LM_DBG("update state for %.*s in group %d to %d\n", address->len,
			address->s, group, state);

	while(i < idx->nr) {
		if(idx->dlist[i].uri.len == address->len
				&& strncasecmp(idx->dlist[i].uri.s, address->s, address->len)
						   == 0) {
			/* destination address found */
			old_state = idx->dlist[i].flags;

			/* reset the bits used for states */
			idx->dlist[i].flags &= ~(DS_STATES_ALL);

			/* we need the initial state for inactive counter */
			init_state = state;

			if((state & DS_TRYING_DST) && (old_state & DS_INACTIVE_DST)) {
				/* old state is inactive, new state is trying => keep it inactive
				 * - it has to go first to active state and then to trying */
				state &= ~(DS_TRYING_DST);
				state |= DS_INACTIVE_DST;
			}

			/* set the new states */
			if(state & DS_DISABLED_DST) {
				idx->dlist[i].flags |= DS_DISABLED_DST;
			} else {
				idx->dlist[i].flags |= state;
			}

			if(state & DS_TRYING_DST) {
				idx->dlist[i].message_count++;
				LM_DBG("destination did not replied %d times, threshold %d\n",
						idx->dlist[i].message_count, probing_threshold);
				/* Destination is not replying.. Increasing failure counter */
				if(idx->dlist[i].message_count >= probing_threshold) {
					/* Destination has too much lost messages.. Bringing it to inactive state */
					idx->dlist[i].flags &= ~DS_TRYING_DST;
					idx->dlist[i].flags |= DS_INACTIVE_DST;
					idx->dlist[i].message_count = 0;
					LM_DBG("deactivate destination, threshold %d reached\n",
							probing_threshold);
				}
			} else {
				if(!(init_state & DS_TRYING_DST)
						&& (old_state & DS_INACTIVE_DST)) {
					idx->dlist[i].message_count++;
					/* Destination was inactive but it is just replying.. Increasing successful counter */
					if(idx->dlist[i].message_count < inactive_threshold) {
						/* Destination has not enough successful replies.. Leaving it into inactive state */
						idx->dlist[i].flags |= DS_INACTIVE_DST;
						/* if destination was in probing state, we stay there for now */
						if((old_state & DS_PROBING_DST) != 0) {
							idx->dlist[i].flags |= DS_PROBING_DST;
						}
						LM_DBG("destination replied successful %d times, "
							   "threshold %d\n",
								idx->dlist[i].message_count,
								inactive_threshold);
					} else {
						/* Destination has enough replied messages.. Bringing it to active state */
						idx->dlist[i].message_count = 0;
						LM_DBG("activate destination, threshold %d reached\n",
								inactive_threshold);
					}
				} else {
					idx->dlist[i].message_count = 0;
				}
			}

			if(!ds_skip_dst(old_state) && ds_skip_dst(idx->dlist[i].flags)) {
				ds_run_route(msg, address, "dispatcher:dst-down", rctx);

			} else {
				if(ds_skip_dst(old_state) && !ds_skip_dst(idx->dlist[i].flags))
					ds_run_route(msg, address, "dispatcher:dst-up", rctx);
			}
			if(idx->dlist[i].attrs.rweight > 0)
				ds_reinit_rweight_on_state_change(
						old_state, idx->dlist[i].flags, idx);

			LM_DBG("old state was %d, set new state to %d\n", old_state,
					idx->dlist[i].flags);
			return 0;
		}
		i++;
	}

	return -1;
}

/**
 *
 */
static ds_rctx_t *_ds_rctx = NULL;

/**
 *
 */
ds_rctx_t *ds_get_rctx(void)
{
	return _ds_rctx;
}

static void ds_run_route(sip_msg_t *msg, str *uri, char *route, ds_rctx_t *rctx)
{
	int rt, backup_rt;
	struct run_act_ctx ctx;
	sip_msg_t *fmsg;
	sr_kemi_eng_t *keng = NULL;
	str evname;

	if(route == NULL) {
		LM_ERR("bad route\n");
		return;
	}

	LM_DBG("executing event_route[%s]\n", route);

	rt = -1;
	if(ds_event_callback.s == NULL || ds_event_callback.len <= 0) {
		rt = route_lookup(&event_rt, route);
		if(rt < 0 || event_rt.rlist[rt] == NULL) {
			LM_DBG("route does not exist");
			return;
		}
	} else {
		keng = sr_kemi_eng_get();
		if(keng == NULL) {
			LM_DBG("event callback (%s) set, but no cfg engine\n",
					ds_event_callback.s);
			return;
		}
	}

	if(msg == NULL) {
		if(faked_msg_init() < 0) {
			LM_ERR("faked_msg_init() failed\n");
			return;
		}
		fmsg = faked_msg_next();
		fmsg->parsed_orig_ruri_ok = 0;
		fmsg->new_uri = *uri;
	} else {
		fmsg = msg;
	}

	if(rt >= 0 || ds_event_callback.len > 0) {
		_ds_rctx = rctx;
		backup_rt = get_route_type();
		set_route_type(REQUEST_ROUTE);
		init_run_actions_ctx(&ctx);
		if(rt >= 0) {
			run_top_route(event_rt.rlist[rt], fmsg, 0);
		} else {
			if(keng != NULL) {
				evname.s = route;
				evname.len = strlen(evname.s);
				if(sr_kemi_route(
						   keng, fmsg, EVENT_ROUTE, &ds_event_callback, &evname)
						< 0) {
					LM_ERR("error running event route kemi callback\n");
				}
			}
		}
		set_route_type(backup_rt);
		_ds_rctx = NULL;
	}
}


/**
 * recalculate relative states if some destination state was changed
 */
int ds_reinit_rweight_on_state_change(
		int old_state, int new_state, ds_set_t *dset)
{
	if(dset == NULL) {
		LM_ERR("destination set is null\n");
		return -1;
	}
	if((!ds_skip_dst(old_state) && ds_skip_dst(new_state))
			|| (ds_skip_dst(old_state) && !ds_skip_dst(new_state))) {
		dp_init_relative_weights(dset);
	}

	return 0;
}


/**
 *
 */
int ds_reinit_state(int group, str *address, int state)
{
	int i = 0;
	ds_set_t *idx = NULL;

	if(_ds_list == NULL || _ds_list_nr <= 0) {
		LM_ERR("the list is null\n");
		return -1;
	}

	/* get the index of the set */
	if(ds_get_index(group, *ds_crt_idx, &idx) != 0) {
		LM_ERR("destination set [%d] not found\n", group);
		return -1;
	}

	for(i = 0; i < idx->nr; i++) {
		if(idx->dlist[i].uri.len == address->len
				&& strncasecmp(idx->dlist[i].uri.s, address->s, address->len)
						   == 0) {
			int old_state = idx->dlist[i].flags;
			/* reset the bits used for states */
			idx->dlist[i].flags &= ~(DS_STATES_ALL);
			/* set the new states */
			idx->dlist[i].flags |= state;
			if(idx->dlist[i].attrs.rweight > 0) {
				ds_reinit_rweight_on_state_change(
						old_state, idx->dlist[i].flags, idx);
			}

			return 0;
		}
	}
	LM_ERR("destination address [%d : %.*s] not found\n", group, address->len,
			address->s);
	return -1;
}

/**
 *
 */
int ds_reinit_duid_state(int group, str *vduid, int state)
{
	int i = 0;
	ds_set_t *idx = NULL;

	if(_ds_list == NULL || _ds_list_nr <= 0) {
		LM_ERR("the list is null\n");
		return -1;
	}

	/* get the index of the set */
	if(ds_get_index(group, *ds_crt_idx, &idx) != 0) {
		LM_ERR("destination set [%d] not found\n", group);
		return -1;
	}

	for(i = 0; i < idx->nr; i++) {
		if(idx->dlist[i].attrs.duid.len == vduid->len
				&& strncasecmp(idx->dlist[i].attrs.duid.s, vduid->s, vduid->len)
						   == 0) {
			int old_state = idx->dlist[i].flags;
			/* reset the bits used for states */
			idx->dlist[i].flags &= ~(DS_STATES_ALL);
			/* set the new states */
			idx->dlist[i].flags |= state;
			if(idx->dlist[i].attrs.rweight > 0) {
				ds_reinit_rweight_on_state_change(
						old_state, idx->dlist[i].flags, idx);
			}

			return 0;
		}
	}
	LM_ERR("destination duid [%d : %.*s] not found\n", group, vduid->len,
			vduid->s);
	return -1;
}

/**
 *
 */
int ds_reinit_state_all(int group, int state)
{
	int i = 0;
	ds_set_t *idx = NULL;

	if(_ds_list == NULL || _ds_list_nr <= 0) {
		LM_ERR("the list is null\n");
		return -1;
	}

	/* get the index of the set */
	if(ds_get_index(group, *ds_crt_idx, &idx) != 0) {
		LM_ERR("destination set [%d] not found\n", group);
		return -1;
	}

	for(i = 0; i < idx->nr; i++) {
		int old_state = idx->dlist[i].flags;
		/* reset the bits used for states */
		idx->dlist[i].flags &= ~(DS_STATES_ALL);
		/* set the new states */
		idx->dlist[i].flags |= state;
		if(idx->dlist[i].attrs.rweight > 0) {
			ds_reinit_rweight_on_state_change(
					old_state, idx->dlist[i].flags, idx);
		}
	}
	return 0;
}

/**
 *
 */
void ds_fprint_set(FILE *fout, ds_set_t *node)
{
	int i, j;

	if(!node)
		return;

	for(i = 0; i < 2; ++i)
		ds_fprint_set(fout, node->next[i]);

	for(j = 0; j < node->nr; j++) {
		fprintf(fout, "\n set #%d\n", node->id);

		if(node->dlist[j].flags & DS_DISABLED_DST)
			fprintf(fout, "    Disabled         ");
		else if(node->dlist[j].flags & DS_INACTIVE_DST)
			fprintf(fout, "    Inactive         ");
		else if(node->dlist[j].flags & DS_TRYING_DST) {
			fprintf(fout, "    Trying");
			/* print the tries for this host. */
			if(node->dlist[j].message_count > 0) {
				fprintf(fout, " (Fail %d/%d)", node->dlist[j].message_count,
						probing_threshold);
			} else {
				fprintf(fout, "           ");
			}

		} else {
			fprintf(fout, "    Active           ");
		}
		if(node->dlist[j].flags & DS_PROBING_DST)
			fprintf(fout, "(P)");
		else
			fprintf(fout, "(*)");

		fprintf(fout, "   %.*s\n", node->dlist[j].uri.len,
				node->dlist[j].uri.s);
	}
}

/**
 *
 */
int ds_fprint_list(FILE *fout)
{
	if(_ds_list == NULL || _ds_list_nr <= 0) {
		LM_ERR("no destination sets\n");
		return -1;
	}

	fprintf(fout, "\nnumber of destination sets: %d\n", _ds_list_nr);

	ds_fprint_set(fout, _ds_list);

	return 0;
}

static int ds_set_vars(
		sip_msg_t *_m, ds_set_t *node, int idx, int export_set_pv)
{
	pv_value_t val;
	if(!node)
		return -1;

	if(export_set_pv && ds_setid_pvname.s != 0) {
		memset(&val, 0, sizeof(pv_value_t));
		val.flags = PV_VAL_INT | PV_TYPE_INT;

		val.ri = node->id;
		if(ds_setid_pv.setf(_m, &ds_setid_pv.pvp, (int)EQ_T, &val) < 0) {
			LM_ERR("setting PV failed\n");
			return -2;
		}
	}
	if(ds_attrs_pvname.s != 0 && node->dlist[idx].attrs.body.len > 0) {
		memset(&val, 0, sizeof(pv_value_t));
		val.flags = PV_VAL_STR;
		val.rs = node->dlist[idx].attrs.body;
		if(ds_attrs_pv.setf(_m, &ds_attrs_pv.pvp, (int)EQ_T, &val) < 0) {
			LM_ERR("setting attrs pv failed\n");
			return -3;
		}
	}
	return 1;
}

int ds_is_addr_from_set(sip_msg_t *_m, struct ip_addr *pipaddr,
		unsigned short tport, unsigned short tproto, ds_set_t *node, int mode,
		int export_set_pv)
{
	ip_addr_t *ipa;
	ip_addr_t ipaddress;
	char hn[DS_HN_SIZE];
	struct hostent *he;
	int j;
	int node_strictness;
	unsigned short sport = 0;
	char sproto = PROTO_NONE;

	for(j = 0; j < node->nr; j++) {
		if(node->dlist[j].irmode & DS_IRMODE_NOIPADDR) {
			/* dst record using hotname with dns not done - no ip to match */
			continue;
		}
		if(!(ds_dns_mode & DS_DNS_MODE_ALWAYS)) {
			ipa = &node->dlist[j].ip_address;
		} else {
			dns_set_local_ttl(ds_dns_ttl);
			if(ds_dns_mode & DS_DNS_MODE_QSRV) {
				sport = node->dlist[j].port;
				sproto = (char)node->dlist[j].proto;
				he = sip_resolvehost(&node->dlist[j].host, &sport, &sproto);
				if(he != 0) {
					if(sport != 0) {
						node->dlist[j].port = sport;
					}
					if(sproto != PROTO_NONE) {
						node->dlist[j].proto = sproto;
					}
				}
			} else {
				memcpy(hn, node->dlist[j].host.s, node->dlist[j].host.len);
				hn[node->dlist[j].host.len] = '\0';
				he = resolvehost(hn);
			}
			dns_set_local_ttl(0);
			if(he == 0) {
				LM_WARN("could not resolve %.*s (skipping)\n",
						node->dlist[j].host.len, node->dlist[j].host.s);
				continue;
			} else {
				/* Store hostent in the dispatcher structure */
				hostent2ip_addr(&ipaddress, he, 0);
				ipa = &ipaddress;
			}
		}
		if(ip_addr_cmp(pipaddr, ipa)
				&& ((mode & DS_MATCH_NOPORT) || node->dlist[j].port == 0
						|| tport == node->dlist[j].port
						|| (mode & DS_MATCH_MIXSOCKPRPORT))
				&& ((mode & DS_MATCH_NOPROTO) || tproto == node->dlist[j].proto
						|| (mode & DS_MATCH_MIXSOCKPRPORT))
				&& (((mode & DS_MATCH_ACTIVE)
							&& !ds_skip_dst(node->dlist[j].flags))
						|| !(mode & DS_MATCH_ACTIVE))
				&& (((mode & DS_MATCH_SOCKET)
							&& node->dlist[j].sock == _m->rcv.bind_address)
						|| !node->dlist[j].sock || !(mode & DS_MATCH_SOCKET))) {

			if(mode & DS_MATCH_MIXSOCKPRPORT) {
				node_strictness = DS_MATCHED_ADDR;
				if(node->dlist[j].port) {
					if(tport != node->dlist[j].port)
						continue;
					else
						node_strictness |= DS_MATCHED_PORT;
				}

				if(node->dlist[j].proto) {
					if(tproto != node->dlist[j].proto)
						continue;
					else
						node_strictness |= DS_MATCHED_PROTO;
				}

				if(node->dlist[j].sock) {
					if(node->dlist[j].sock != _m->rcv.bind_address)
						continue;
					else
						node_strictness |= DS_MATCHED_SOCK;
				}

				if(node_strictness
						== (DS_MATCHED_ADDR | DS_MATCHED_PORT | DS_MATCHED_PROTO
								| DS_MATCHED_SOCK))
					return ds_set_vars(_m, node, j, export_set_pv);

				if(ds_strictness < node_strictness) {
					ds_strictness = node_strictness;
					ds_strictest_node = node;
					ds_strictest_idx = j;
				}
				continue;
			}

			return ds_set_vars(_m, node, j, export_set_pv);
		}
	}
	return -1;
}

/**
 *
 */
int ds_is_addr_from_set_r(sip_msg_t *_m, struct ip_addr *pipaddr,
		unsigned short tport, unsigned short tproto, ds_set_t *node, int mode,
		int export_set_pv)
{
	int i, rc;

	if(!node)
		return -1;

	for(i = 0; i < 2; ++i) {
		rc = ds_is_addr_from_set_r(
				_m, pipaddr, tport, tproto, node->next[i], mode, export_set_pv);
		if(rc != -1)
			return rc;
	}

	return ds_is_addr_from_set(
			_m, pipaddr, tport, tproto, node, mode, export_set_pv);
}

/* Checks, if the request (sip_msg *_m) comes from a host in a group
 * (group-id or -1 for all groups)
 */
int ds_is_addr_from_list(sip_msg_t *_m, int group, str *uri, int mode)
{
	ds_set_t *list;

	struct ip_addr *pipaddr;
	struct ip_addr aipaddr;
	unsigned short tport;
	unsigned short tproto;
	unsigned short sport = 0;
	char sproto = PROTO_NONE;
	sip_uri_t puri;
	char hn[DS_HN_SIZE];
	struct hostent *he;
	int rc = -1;

	if(uri == NULL || uri->len <= 0) {
		pipaddr = &_m->rcv.src_ip;
		tport = _m->rcv.src_port;
		tproto = _m->rcv.proto;
	} else {
		if(parse_uri(uri->s, uri->len, &puri) != 0
				|| puri.host.len > (DS_HN_SIZE - 2)) {
			LM_ERR("bad uri [%.*s]\n", uri->len, uri->s);
			return -1;
		}
		tport = puri.port_no;
		tproto = puri.proto;
		dns_set_local_ttl(ds_dns_ttl);
		if(ds_dns_mode & DS_DNS_MODE_QSRV) {
			sport = tport;
			sproto = (char)tproto;
			he = sip_resolvehost(&puri.host, &sport, &sproto);
			if(he != 0) {
				if(sport != 0) {
					tport = sport;
				}
				if(sproto != PROTO_NONE) {
					tproto = (unsigned short)sproto;
				}
			}
		} else {
			memcpy(hn, puri.host.s, puri.host.len);
			hn[puri.host.len] = '\0';
			he = resolvehost(hn);
		}
		dns_set_local_ttl(0);
		if(he == 0) {
			LM_ERR("could not resolve %.*s\n", puri.host.len, puri.host.s);
			return -1;
		}
		hostent2ip_addr(&aipaddr, he, 0);
		pipaddr = &aipaddr;
	}


	if(mode & DS_MATCH_MIXSOCKPRPORT) {
		ds_strictness = 0;
		ds_strictest_node = NULL;
	}

	if(group == -1) {
		rc = ds_is_addr_from_set_r(
				_m, pipaddr, tport, tproto, _ds_list, mode, 1);
	} else {
		list = ds_avl_find(_ds_list, group);
		if(list) {
			rc = ds_is_addr_from_set(_m, pipaddr, tport, tproto, list, mode, 0);
		}
	}

	if(rc == -1 && (mode & DS_MATCH_MIXSOCKPRPORT) && ds_strictest_node) {
		rc = ds_set_vars(
				_m, ds_strictest_node, ds_strictest_idx, group == -1 ? 1 : 0);
	}

	return rc;
}

int ds_is_from_list(struct sip_msg *_m, int group)
{
	return ds_is_addr_from_list(_m, group, NULL, DS_MATCH_NOPROTO);
}

/**
 * Check if the a group has any or a specific active uri
 */
int ds_is_active_uri(sip_msg_t *msg, int group, str *uri)
{
	ds_set_t *list;
	int j;

	list = ds_avl_find(_ds_list, group);
	if(list) {
		for(j = 0; j < list->nr; j++) {
			if(!ds_skip_dst(list->dlist[j].flags)) {
				if(uri == NULL || uri->s == NULL || uri->len <= 0) {
					return 1;
				}
				if((list->dlist[j].uri.len == uri->len)
						&& (memcmp(list->dlist[j].uri.s, uri->s, uri->len)
								== 0)) {
					return 1;
				}
			}
		}
	}

	return -1;
}

/*! \brief
 * Callback-Function for the OPTIONS-Request
 * This Function is called, as soon as the Transaction is finished
 * (e. g. a Response came in, the timeout was hit, ...)
 */
static void ds_options_callback(
		struct cell *t, int type, struct tmcb_params *ps)
{
	int group = 0;
	str uri = {0, 0};
	sip_msg_t *fmsg;
	int state;
	ds_rctx_t rctx;

	/* The param contains the group, in which the failed host
	 * can be found.*/
	if(ps->param == NULL) {
		LM_DBG("No parameter provided, OPTIONS-Request was finished"
			   " with code %d\n",
				ps->code);
		return;
	}

	fmsg = NULL;

	/* The param is a (void*) Pointer, so we need to dereference it and
	 *  cast it to an int. */
	group = (int)(long)(*ps->param);
	/* The SIP-URI is taken from the Transaction.
	 * Remove the "To: <" (s+5) and the trailing >+new-line (s - 5 (To: <)
	 * - 3 (>\r\n)). */
	uri.s = t->to_hdr.s + 5;
	uri.len = t->to_hdr.len - 8;
	LM_DBG("OPTIONS-Request was finished with code %d (to %.*s, group %d)\n",
			ps->code, uri.len, uri.s, group);
	if(ds_ping_latency_stats) {
		ds_update_latency(group, &uri, ps->code);
	}

	memset(&rctx, 0, sizeof(ds_rctx_t));
	rctx.code = ps->code;
	if(ps->rpl != NULL) {
		if(ps->rpl != FAKED_REPLY) {
			rctx.flags |= 1;
			rctx.reason = ps->rpl->first_line.u.reply.reason;
		}
	}

	/* Check if in the meantime someone disabled probing of the target
	 * through RPC or reload */
	if(ds_probing_mode == DS_PROBE_ONLYFLAGGED
			&& !(ds_get_state(group, &uri) & DS_PROBING_DST)) {
		return;
	}

	/* ps->code contains the result-code of the request.
	 * We accept both a "200 OK" or the configured reply as a valid response */
	if((ps->code >= 200 && ps->code <= 299)
			|| ds_ping_check_rplcode(ps->code)) {
		/* Set the according entry back to "Active" */
		state = 0;
		if(ds_probing_mode == DS_PROBE_ALL
				|| ((ds_probing_mode == DS_PROBE_ONLYFLAGGED)
						&& (ds_get_state(group, &uri) & DS_PROBING_DST)))
			state |= DS_PROBING_DST;

		/* Check if in the meantime someone disabled the target through RPC */
		if(!(ds_get_state(group, &uri) & DS_DISABLED_DST)
				&& ds_update_state(fmsg, group, &uri, state, &rctx) != 0) {
			LM_ERR("Setting the state failed (%.*s, group %d)\n", uri.len,
					uri.s, group);
		}
	} else {
		state = DS_TRYING_DST;
		if(ds_probing_mode != DS_PROBE_NONE)
			state |= DS_PROBING_DST;
		/* Check if in the meantime someone disabled the target through RPC */
		if(!(ds_get_state(group, &uri) & DS_DISABLED_DST)
				&& ds_update_state(fmsg, group, &uri, state, &rctx) != 0) {
			LM_ERR("Setting the probing state failed (%.*s, group %d)\n",
					uri.len, uri.s, group);
		}
	}

	return;
}

/*
 * Small helper to decide to ping a gateway or not
 */
static inline int ds_ping_result_helper(ds_set_t *node, int j)
{
	/* probe all */
	if(ds_probing_mode == DS_PROBE_ALL) {
		LM_DBG("probe all, mode DS_PROBE_ALL\n");
		return 1;
	}
	/* probe if probing is set, but not in mode DS_PROBE_INACTIVE */
	if(ds_probing_mode != DS_PROBE_INACTIVE
			&& (node->dlist[j].flags & DS_PROBING_DST) != 0) {
		LM_DBG("probing set, but not mode DS_PROBE_INACTIVE\n");
		return 1;
	}
	/* probe for mode DS_PROBE_INACTIVE only for inactive and probing gw */
	if(ds_probing_mode == DS_PROBE_INACTIVE
			&& (node->dlist[j].flags & DS_PROBING_DST) != 0
			&& (node->dlist[j].flags & DS_INACTIVE_DST) != 0) {
		LM_DBG("probing and inactive set, mode DS_PROBE_INACTIVE\n");
		return 1;
	}
	return 0;
}

/**
 *
 */
void ds_ping_set(ds_set_t *node)
{
	uac_req_t uac_r;
	int i, j;
	str ping_from;
	str obproxy;
	int state;
	ds_rctx_t rctx;

	if(!node)
		return;

	for(i = 0; i < 2; ++i)
		ds_ping_set(node->next[i]);

	for(j = 0; j < node->nr; j++) {
		/* skip addresses set in disabled state by admin */
		if((node->dlist[j].flags & DS_DISABLED_DST) != 0)
			continue;
		/* skip addresses with no-ping flag */
		if((node->dlist[j].flags & DS_NOPING_DST) != 0)
			continue;
		/* If the Flag of the entry has "Probing set, send a probe:	*/
		if(ds_ping_result_helper(node, j)) {
			LM_DBG("probing set #%d, URI %.*s\n", node->id,
					node->dlist[j].uri.len, node->dlist[j].uri.s);

			/* Send ping using TM-Module.
			 * int request(str* m, str* ruri, str* to, str* from, str* h,
			 *		str* b, str *oburi,
			 *		transaction_cb cb, void* cbp); */
			set_uac_req(&uac_r, &ds_ping_method, 0, 0, 0, TMCB_LOCAL_COMPLETED,
					ds_options_callback, (void *)(long)node->id);
			if(node->dlist[j].attrs.sockname.s != NULL
					&& node->dlist[j].attrs.sockname.len > 0) {
				uac_r.ssockname = &node->dlist[j].attrs.sockname;
			} else if(node->dlist[j].attrs.socket.s != NULL
					  && node->dlist[j].attrs.socket.len > 0) {
				uac_r.ssock = &node->dlist[j].attrs.socket;
			} else if(ds_default_sockname.s != NULL
					  && ds_default_sockname.len > 0) {
				uac_r.ssockname = &ds_default_sockname;
			} else if(ds_default_socket.s != NULL
					  && ds_default_socket.len > 0) {
				uac_r.ssock = &ds_default_socket;
			}

			/* Overwrite default ping From URI with attribute */
			if(node->dlist[j].attrs.ping_from.s != NULL
					&& node->dlist[j].attrs.ping_from.len > 0) {
				ping_from = node->dlist[j].attrs.ping_from;
				LM_DBG("ping_from: %.*s\n", ping_from.len, ping_from.s);
			} else {
				ping_from = ds_ping_from;
				LM_DBG("Default ping_from: %.*s\n", ping_from.len, ping_from.s);
			}

			if(node->dlist[j].attrs.obproxy.s != NULL
					&& node->dlist[j].attrs.obproxy.len > 0) {
				obproxy = node->dlist[j].attrs.obproxy;
				LM_DBG("outbound proxy: %.*s\n", obproxy.len, obproxy.s);
			} else {
				obproxy = ds_outbound_proxy;
				LM_DBG("Default outbound proxy: %.*s\n", ds_outbound_proxy.len,
						ds_outbound_proxy.s);
			}

			gettimeofday(&node->dlist[j].latency_stats.start, NULL);

			if(tmb.t_request(&uac_r, &node->dlist[j].uri, &node->dlist[j].uri,
					   &ping_from, &obproxy)
					< 0) {
				LM_ERR("unable to ping [%.*s] in group [%d]\n",
						node->dlist[j].uri.len, node->dlist[j].uri.s, node->id);
				state = DS_TRYING_DST;
				if(ds_probing_mode != DS_PROBE_NONE) {
					state |= DS_PROBING_DST;
				}
				memset(&rctx, 0, sizeof(ds_rctx_t));
				rctx.code = 500;
				rctx.reason.s = "Sending keepalive failed";
				rctx.reason.len = 24;
				/* check if meantime someone disabled the target via RPC */
				if(!(node->dlist[j].flags & DS_DISABLED_DST)
						&& ds_update_state(NULL, node->id, &node->dlist[j].uri,
								   state, &rctx)
								   != 0) {
					LM_ERR("Setting the probing state failed (%.*s, group "
						   "%d)\n",
							node->dlist[j].uri.len, node->dlist[j].uri.s,
							node->id);
				}
			}
		}
	}
}

/*! \brief
 * Timer for checking probing destinations
 *
 * This timer is regularly fired.
 */
void ds_check_timer(unsigned int ticks, void *param)
{


	/* Check for the list. */
	if(_ds_list == NULL || _ds_list_nr <= 0) {
		LM_DBG("no destination sets\n");
		return;
	}

	if(_ds_ping_active != NULL && *_ds_ping_active == 0) {
		LM_DBG("pinging destinations is inactive by admin\n");
		return;
	}

	ds_ping_set(_ds_list);
}

/*! \brief
 * Timer for checking expired items in call load dispatching
 *
 * This timer is regularly fired.
 */
void ds_ht_timer(unsigned int ticks, void *param)
{
	ds_cell_t *it;
	ds_cell_t *it0;
	time_t now;
	int i;

	if(_dsht_load == NULL)
		return;

	now = time(NULL);

	for(i = 0; i < _dsht_load->htsize; i++) {
		/* free entries */
		lock_get(&_dsht_load->entries[i].lock);
		it = _dsht_load->entries[i].first;
		while(it) {
			it0 = it->next;
			if((it->expire != 0 && it->expire < now)
					|| (it->state == DS_LOAD_INIT && it->initexpire != 0
							&& it->initexpire < now)) {
				/* expired */
				if(it->prev == NULL)
					_dsht_load->entries[i].first = it->next;
				else
					it->prev->next = it->next;
				if(it->next)
					it->next->prev = it->prev;
				_dsht_load->entries[i].esize--;

				/* execute ds unload callback */
				ds_load_remove_byid(it->dset, &it->duid);

				ds_cell_free(it);
			}
			it = it0;
		}
		lock_release(&_dsht_load->entries[i].lock);
	}
	return;
}


/**
 *
 */
void ds_dns_update_set(ds_set_t *node)
{
	int i, j;
	char hn[DS_HN_SIZE];
	struct hostent *he;
	unsigned short sport = 0;
	char sproto = PROTO_NONE;

	if(!node)
		return;

	for(i = 0; i < 2; ++i)
		ds_dns_update_set(node->next[i]);

	for(j = 0; j < node->nr; j++) {
		/* do a DNS qookup for the host part, if not disabled via dst flags */
		if(node->dlist[j].flags & DS_NODNSARES_DST) {
			continue;
		}
		if(node->dlist[j].host.len <= 0) {
			continue;
		}
		LM_DBG("resolving [%.*s] - mode: %d\n", node->dlist[j].host.len,
				node->dlist[j].host.s, ds_dns_mode);
		dns_set_local_ttl(ds_dns_ttl);
		if(ds_dns_mode & DS_DNS_MODE_QSRV) {
			sport = node->dlist[j].port;
			sproto = (char)node->dlist[j].proto;
			he = sip_resolvehost(&node->dlist[j].host, &sport, &sproto);
			if(he != 0) {
				if(sport != 0) {
					node->dlist[j].port = sport;
				}
				if(sproto != PROTO_NONE) {
					node->dlist[j].proto = sproto;
				}
			}
		} else {
			/* The Hostname needs to be \0 terminated for resolvehost, so we
			 * make a copy here. */
			memcpy(hn, node->dlist[j].host.s, node->dlist[j].host.len);
			hn[node->dlist[j].host.len] = '\0';
			he = resolvehost(hn);
		}
		dns_set_local_ttl(0);
		if(he == 0) {
			LM_ERR("could not resolve %.*s\n", node->dlist[j].host.len,
					node->dlist[j].host.s);
			continue;
		} else {
			/* Store hostent in the dispatcher structure */
			hostent2ip_addr(&node->dlist[j].ip_address, he, 0);
			gettimeofday(&node->dlist[j].dnstime, NULL);
		}
	}
}

/*! \brief
 * Timer for DNS query of destination addresses
 *
 * This timer is regularly fired.
 */
void ds_dns_timer(unsigned int ticks, void *param)
{
	if(!(ds_dns_mode & DS_DNS_MODE_TIMER)) {
		return;
	}

	/* Check for the list. */
	if(_ds_list == NULL || _ds_list_nr <= 0) {
		LM_DBG("no destination sets\n");
		return;
	}

	ds_dns_update_set(_ds_list);
}

int ds_next_dst_api(sip_msg_t *msg, int mode)
{
	return ds_update_dst(msg, DS_USE_NEXT, mode);
}

int bind_dispatcher(dispatcher_api_t *api)
{
	if(!api) {
		ERR("Invalid parameter value\n");
		return -1;
	}
	api->select = ds_select_dst;
	api->next = ds_next_dst_api;
	api->mark = ds_mark_dst;
	api->is_from = ds_is_from_list;
	return 0;
}


ds_set_t *ds_get_list(void)
{
	return _ds_list;
}

int ds_get_list_nr(void)
{
	return _ds_list_nr;
}

ds_set_t *ds_avl_find(ds_set_t *node, int id)
{
	int next_step;

	while(node && id != node->id) {
		next_step = (id > node->id);
		node = node->next[next_step];
	}
	return node;
}

/**
 *
 */
void ds_avl_destroy(ds_set_t **node_ptr)
{
	ds_set_t *node = NULL;
	ds_dest_t *dest = NULL;
	int i = 0;

	if(!node_ptr || !(*node_ptr))
		return;

	node = *node_ptr;

	for(i = 0; i < 2; ++i)
		ds_avl_destroy(&node->next[i]);

	for(dest = node->dlist; dest != NULL; dest = dest->next) {
		if(dest->uri.s != NULL) {
			shm_free(dest->uri.s);
			dest->uri.s = NULL;
		}
		if(dest->attrs.body.s != NULL) {
			shm_free(dest->attrs.body.s);
			dest->attrs.body.s = NULL;
		}
	}
	if(node->dlist != NULL)
		shm_free(node->dlist);
	shm_free(node);

	*node_ptr = NULL;

	return;
}

static void avl_rebalance(ds_set_t **path_top, int target);

ds_set_t *ds_avl_insert(ds_set_t **root, int id, int *setn)
{
	ds_set_t **rotation_top;
	ds_set_t *node;
	int next_step;

	rotation_top = root;
	node = *root;

	while(node && id != node->id) {
		next_step = (id > node->id);
		if(!AVL_BALANCED(node))
			rotation_top = root;
		root = &node->next[next_step];
		node = *root;
	}
	if(!node) {
		node = shm_malloc(sizeof(ds_set_t));
		if(!(node)) {
			SHM_MEM_ERROR;
			return NULL;
		}
		memset(node, 0, sizeof(ds_set_t));
		node->id = id;
		node->longer = AVL_NEITHER;
		*root = node;
		lock_init(&node->lock);
		avl_rebalance(rotation_top, id);

		(*setn)++;
	}
	return node;
}

static void avl_rebalance_path(ds_set_t *path, int id)
{
	int next_step;
	/* Each node in path is currently balanced.
	 * Until we find target, mark each node as longer
	 * in the direction of target because we know we have
	 * inserted target there
	 */
	while(path && id != path->id) {
		next_step = (id > path->id);
		path->longer = next_step;
		path = path->next[next_step];
	}
}

static ds_set_t *avl_rotate_2(ds_set_t **path_top, int dir)
{
	ds_set_t *B, *C, *D, *E;

	B = *path_top;
	D = B->next[dir];
	C = D->next[1 - dir];
	E = D->next[dir];
	*path_top = D;
	D->next[1 - dir] = B;
	B->next[dir] = C;
	B->longer = AVL_NEITHER;
	D->longer = AVL_NEITHER;

	return E;
}

static ds_set_t *avl_rotate_3(ds_set_t **path_top, int dir, int third)
{
	ds_set_t *B, *F, *D, *C, *E;

	B = *path_top;
	F = B->next[dir];
	D = F->next[1 - dir];
	/* node: C and E can be NULL */
	C = D->next[1 - dir];
	E = D->next[dir];
	*path_top = D;
	D->next[1 - dir] = B;
	D->next[dir] = F;
	B->next[dir] = C;
	F->next[1 - dir] = E;
	D->longer = AVL_NEITHER;

	/* assume both trees are balanced */
	B->longer = F->longer = AVL_NEITHER;

	if(third == AVL_NEITHER)
		return NULL;

	if(third == dir) {
		/* E holds the insertion so B is unbalanced */
		B->longer = 1 - dir;
		return E;
	} else {
		/* C holds the insertion so F is unbalanced */
		F->longer = dir;
		return C;
	}
}

static void avl_rebalance(ds_set_t **path_top, int id)
{
	ds_set_t *path;
	int first, second, third;

	path = *path_top;

	if(AVL_BALANCED(path)) {
		avl_rebalance_path(path, id);
		return;
	}
	first = (id > path->id);
	if(path->longer != first) {
		/* took the shorter path */
		path->longer = AVL_NEITHER;
		avl_rebalance_path(path->next[first], id);
		return;
	}
	/* took the longer path, need to rotate */
	second = (id > path->next[first]->id);
	if(first == second) {
		/* just a two-point rotate */
		path = avl_rotate_2(path_top, first);
		avl_rebalance_path(path, id);
		return;
	}
	/* fine details of the 3 point rotate depend on the third step.
	 * However there may not be a third step, if the third point of the
	 * rotation is the newly inserted point.  In that case we record
	 * the third step as NEITHER
	 */
	path = path->next[first]->next[second];
	if(id == path->id)
		third = AVL_NEITHER;
	else
		third = (id > path->id);
	path = avl_rotate_3(path_top, first, third);
	avl_rebalance_path(path, id);
}
